Fabricação de microcanais para integração de uma língua eletrônica em um sistema lab-on-a-chip

Dantas, Cléber Aparecido Rocha [UNESP]

25 June 2009

Made available in DSpace on 2014-06-11T19:23:08Z (GMT). No. of bitstreams: 0 Previous issue date: 2009-06-25Bitstream added on 2014-06-13T20:30:01Z : No. of bitstreams: 1 dantas_car_me_bauru.pdf: 1072201 bytes, checksum: 3b91c91a3b84d11cccc4310009eed914 (MD5) / Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) / Fabricamos neste trabalho microcanais em uma matriz de PDMS para otimização de uma configuração que permita, futuramente, a inserção de eletrodos interdigitados no interior dos mesmos para a integração da língua eletrônica que estamos trabalhando ao longo dos últimos anos com dispositivos lab-on-a-chip. O objetivo final é a fabricação de um sensor tongue-on-a-chip, não havendo nada similar na literatura até o presente momento, tendo-se em vista, principalmente, o potencial de aplicação de ambos dispositivos (língua eletrônica e lab-on-a-chip). Neste sentido, esta dissertação torna-se uma chave importante para o desenvolvimento de uma tecnologia nova e com forte apelo comercial. Como a fabricação dos microcanais envolve técnicas e equipamentos de litografia que não dispomos em nossos laboratórios, estendemos colaborações com o laboratório Nacional de Luz Síncroton (LNLS - através de um projeto específico nessa linha de atuação), onde fabricamos os microcanais e eletrodos interdigitados envolvidos neste trabalho. Como é a primeira vez que a microfluídica está sendo aplicada em dispositivos do tipo língua eletrônica, tivemos um trabalho minucioso de verificação das melhores condições envolvidas na fabricação dos dispositivos. As medidas em fluxo no interior dos microcanais mostraram-se mais rápidas e eficientes que as estáticas utilizadas anteriormente, e, adicionalmente à redução no volume das amostras analisadas com os microcanais, necessitamos ainda de um refinamento para aplicações futuras (análises clínicas e biológicas, controle ambiental, análise de bebidas...), pois o maior empecilho encontrado até o momento tem sio a selagem do dispositivo devido à deposição de filmes ultrafinos sobre os eletrodos metálicos, que esperamos resolver em trabalhos futuros. / In this work microchannels were fabricated in a PDMS matrix to optimize a configuration that allows, in future works, the insertion of interdigitated electrodes into the microchannel for the integration of the electronic tongue that we have being working in the last couple of years with lab-on-a-chip devices. The final goal is the fabrication of a tongue-on-a-chip sensor, having nothing similar in the literature up to date, bearing in mind the high potential of application of both devices (electronic tongue and lab-on-a-chip). In that sense, this Msc work becomes an important key to the development of a new technology with strong commercial appeal. As the microchannel fabrication needs equipments and techniques not available in our laboratory, we extend the collaboration with the Brazilian Synchrotron Light Laboratory (LNLS - throughout a specific project in this area) where the microchannels and interdigitated electrodes were fabricated. As it is the first time microfluidic is applied in e-tongue sensors, we did a detailed work verifying the best conditions involved in the device fabrication. Flow measurements inside the microchannels shown to be faster and more efficient than the static ones previously made, and, besides the volume reduction of the samples analysed with the microchannels, we still need a refinement for future applications (clinical and biological analysis, environmental control, beverage analysis, ...), as the major problem has being the sealing of the device due to the deposition of ultra-thin films onto the interdigitated electrodes, which we hope to solve in future works.

Ciencia

Tecnologia de materiais

Lab-on-a-chip

Microfluídica

Filme automontado

Electronic tongue

Microfluidic

Self-assembled films

Análise proteômica do soro sanguíneo de ratos adultos submetidos à desnutrição neonatal

de Andrade Bezerra, Alice

31 January 2011

Made available in DSpace on 2014-06-12T15:51:55Z (GMT). No. of bitstreams: 2 arquivo2778_1.pdf: 2467213 bytes, checksum: 266474e44dd114081ad37ccb2d4e5ff1 (MD5) license.txt: 1748 bytes, checksum: 8a4605be74aa9ea9d79846c1fba20a33 (MD5) Previous issue date: 2011 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Estímulos atuantes durante períodos fetal e neonatal desencadeiam modificações fisiológicas e metabólicas permanentes no indivíduo, fenômeno bastante estudado em Nutrição através de manipulação nutricional. Para pesquisa de alterações biomoleculares, o soro sanguíneo é fonte potencial de biomarcadores protéicos. Este estudo teve como objetivo avaliar os efeitos da desnutrição protéica neonatal sobre o perfil proteômico do soro sanguíneo de ratos adultos. Foram utilizados 8 ratos Wistar, machos, adultos, que foram divididos em 2 grupos, de acordo com a dieta disponibilizada do 1º ao 21º dia de vida (período de lactação): grupo nutrido (GN), formado por filhotes cujas mães receberam dieta com 17 % de caseína e grupo desnutrido (GD), no qual as mães alimentaram-se de dieta com 8 % de caseína. No período de reposição nutricional, a partir do desmame (22º dia), os filhotes passaram a receber dieta padrão normoprotéica. Os animais foram pesados diariamente durante aleitamento e, posteriormente, em dias alternados. Na idade adulta, a partir do 90º dia de vida, os animais foram anestesiados e submetidos à punção cardíaca para coleta de sangue (4mL). Após coagulação, este foi centrifugado, a camada de soro coletada e acondicionada a -20ºC. Alíquotas foram inicialmente diluídas (1:10) para análise eletroforética monodimensional pela tecnologia lab-on-a-chip, utilizando os kits Agilent Protein 80 e 230. Para análise bidimensional, proteínas presentes em 50 &#956;L de soro foram precipitadas em acetona, ressolubilizadas em solução (200 &#956;L) contendo uréia (7 M), tiouréia (2 M) e CHAPS (2 %), sendo 100 &#956;L da solução de proteínas reservados para 1ª dimensão (fitas de 13 cm, pH 3-10). A 2ª dimensão foi realizada em géis de poliacrilamida (10 %) que foram corados com Azul de Coomassie. Os spots detectados foram analisados em software específico. Para análise dos dados, utilizaram-se os testes t-Student e Mann-Whitney, considerando-se p&#8804;0,05. Animais GD apresentaram valores de peso corporal menores do que GN a partir do 5º dia de vida (GN: 12,55±3,35g e GD: 10,41±2,03g, p=0,0262), condição que permaneceu até o 90º dia (p<0,0007). Além disso, na idade adulta, apresentaram menor quantidade de faixas de pesos moleculares detectadas e aumento de concentração de proteínas de peso 32,92 a 32,34 kDa (GN: 6,3 ng/&#956;L e GD: 7,45 ng/&#956;L, p=0,041) no perfil monodimensional. Na análise bidimensional, observaram-se alterações aparentes nos tipos e intensidade de alguns spots. A desnutrição protéica neonatal ocasionou déficit permanente de peso corporal até 90º dia de vida e, no animal adulto, provocou modificações nos perfis proteômicos das amostras de soro analisadas. Em decorrência da administração de uma dieta hipoprotéica durante período crítico de desenvolvimento, modificações no proteoma podem ser correlacionadas a alterações metabólicas que, potencialmente, estejam associadas ao desenvolvimento de patologias no indivíduo adulto

Desnutrição neonatal

soro sanguíneo

perfil proteômico

eletroforese bidimensional

tecnologia lab-on-a-chip

High-throughput Cell Encapsulation in Monodisperse Agarose Microcapsules Using a Microfluidic Device

Monette-Catafard, Nicolas

January 2014

Over the last decade, microfluidics has emerged as a distinct new field with promising applications for diverse research areas. The ability to precisely control fluids at the microscale allows the execution of a variety of programmable semi-automatic operations on the same device, effectively forming a lab-on-a-chip. In particular, droplet-based microfluidic systems – which reliably generate highly uniform microdroplets at a high throughput – enable the controlled compartmentalization of biological material and have the potential to influence mainstream biomedical research. In this thesis, a microfluidic platform is presented that allows the encapsulation of viable cells in agarose microcapsules for applications in cell–based therapy. As an improvement to pre-existing methods of cell encapsulation, the proposed system combines continuous high throughput cell-encapsulation with on-chip microcapsule gelation and purification.

Microfluidics

Microcapsules

Cell encapsulation

Agarose

Cell therapy

Regenerative medicine

Lab-on-a-chip

Miniaturised system for DNA analysis

Salman, Abbas Ali Abulwohab

January 2013

The growing markets for analytical techniques in areas such as pathogen detection, clinical analysis, forensic investigation, environmental analysis and food analysis require the development of devices with simultaneous high performance, speed, simplicity and low cost. Analysis of deoxyribonucleic acid (DNA) has been enhanced by use of the polymerase chain reaction (PCR) technique, which is now a widely used tool for in vitro amplification of nucleic acids. In this work, a miniaturised PCR system comprising a microfluidic PCR chip, novel heating method and fluorescence detection unit was developed. PCR chip with reactants were shunted along three temperature zones in a fine polycarbonate chip. The polycarbonate PCR chip was fabricated using milling and thermal fusion binding for sealing of the cover. Thermal-cycling within the microfluidic chip was achieved by programmable shunting of the chip between three double side temperature zones with different temperatures to accomplish the denaturation, annealing and elongation steps necessary for PCR amplification. This thermal-cycling model potentially improves PCR efficacy because it increases the ramping rates for heating and cooling the PCR mixture. The detection unit comprises a photo-detector and Light Emitting Diode (LED) as the source of excitation. The detection limit of the system was determined on the PCR chip using Fluorescein isothiocyanate (FITC) as a fluorophore dye. The detection limit achieved was 7.8 pg ml-1 or (19.7 pmol) of FITC. The chromosomal DNA used in this work was extracted from non-pathogenic K-12 subtype of Escherichia coli (E. coli). The investigations showed that the system was capable of performing PCR amplification with different annealing temperature ranging from 54 to 68 °C, targeting three different sizes of PCR products of 250, 552 and 1500 bp. The prototype thermal-cycler and PCR chip were used successfully to amplify the three sizes and the results were compared with same fragments amplified on a conventional PCR .thermal-cycler machine. The method used for comparison was gel electrophoresis. In addition, a fluorescence detection system was employed for detecting of PCR products using SYBR Green I fluorescent dye. The whole system allows for developments of low cost, easy to use and portable instruments.

572.8

3D Printing for Microfluidics

Gong, Hua

01 November 2018

This dissertation focuses on developing 3D printing as a fabrication method for microfluidic devices. Specifically, I concentrate on the 3D printing approach known as Digital Light Processing stereolithography (DLP-SLA) in which serially projected images are used to sequentially photopolymerize layers to build a microfluidic device. The motivation for this work is to explore a much faster alternative to cleanroom-based microfabrication that additionally offers the opportunity to densely integrate microfluidic elements in compact 3D layouts for dramatic device volume reduction. In the course of my research, an optical approach was used to guide custom resin formulation to help create the interconnected hollow regions that form a microfluidic device. This was based on a new a mathematical model to calculate the optical dose delivered throughout a 3D printed part, which also explains the effect of voids. The model was verified by a series of 3D printed chips fabricated with a commercial 3D printer and a custom resin. Channels as small as 108 µm x 60 µm were repeatably fabricated. Next, highly compact active fluidic components, including valves, pumps, and multiplexers, were fabricated with the same 3D printer and resin. The valves achieved a 10x size reduction compared with previous results, and were the smallest 3D printed valves at the time. Moreover, by adding thermal initiator to thermally cure devices after 3D printing, the durability of 3D printed valves was improved and up to 1 million actuations were demonstrated.To further decrease the 3D printed feature size, I built a custom 3D printer with a 385 nm LED light source and a 7.56 µm pixel pitch in the plane of the projected image. A custom resin was also developed to take advantage of the new 3D printer's features, which necessitated developing a UV absorber screening process which I applied to 20 candidate absorbers. In addition, a new mathematical model was developed to use only the absorber's molar absorptivity measurement to predict the resin optical penetration depth, which is important for determining the z-resolution that can be achieved with a given resin. The final resin formulation uses 2-nitrophenyl phenyl sulfide (NPS) as the UV absorber. With this resin, along with a new channel narrowing technique, I successfully created flow channel cross sections as small as 18 µm x 20 µm.With the custom 3D printer, smaller valves and pumps become possible, which led to the invention of a new method of creating large numbers of high density chip-to-chip microfluidic interconnects based on either simple integrated microgaskets (SIMs) or controlled-compression integrated microgaskets (CCIMs). Since these structures are directly 3D printed as part of a device, they require no additional materials or fabrication steps. As a demonstration of the efficacy of this approach, 121 chip-to-chip interconnects in an 11 x 11 array for both SIMs and CCIMs with an areal density of 53 interconnects per square mm were demonstrated, and tested up to 50 psi without leaking. Finally, these interconnects were used in the development of 3D printed chips with valves having 30x smaller volume than the valves we previously demonstrated. These valves served as a building block for demonstrating the miniaturization potential of an active fluid mixer using our 3D printing tools, materials, and methods. The mixer provided a set of selectable mixing ratios, and was designed in 2 configurations, a linear dilution mixer-pump (LDMP) and a parallelized dilution mixer-pump (PDMP), which occupy volumes of only 1.5 cubic mm and 2.6 cubic mm, respectively.

3D printing

microfluidics

digital light processing

stereolithography

lab on a chip

resin formulation

valve

pump

mixer

interconnect

Engineering

Développement d’un laboratoire sur puce pour la préconcentration sur support monolithique. Application à l'enrichissement et la séparation en ligne de phosphopeptides. / Development of a lab on-a-chip for monolith-based preconcentration and separation of phosphopeptides

Araya-Farias, Monica

22 March 2016

Les laboratoires sur puce sont des dispositifs miniaturisés qui offrent la possibilité d'intégrer en ligne toutes les étapes de la chaîne analytique tout en réduisant les volumes d’échantillon et les temps d’analyse. Ainsi, ils constituent potentiellement un outil de diagnostic particulièrement adapté pour l’analyse de biomarqueurs phosphorylés, pour lesquels une préconcentration est nécessaire en raison de leur faible abondance dans les fluides biologiques. C’est pourquoi, de nouvelles méthodes, dédiées à l'enrichissement de phosphopeptides, ont été développées ces dernières années et en particulier celles utilisant des supports solides basées sur la chromatographie d’affinité sur des ions métalliques immobilisés (IMAC). Parmi les supports solides intégrables en microsystème, les monolithes organiques constituent une option privilégiée grâce à la possibilité d’être synthétisés in situ. Le but de ce travail de thèse était donc de développer un laboratoire sur puce intégrant une préconcentration des phosphopeptides sur support monolithique basé sur le principe de l’IMAC et leur séparation électrophorétique en ligne.Dans un premier temps, nous avons développé deux approches innovantes qui ont permis de synthétiser pour la première fois un monolithe à base d’éthylène glycol méthacrylate phosphate (EGMP) et de bisacrylamide (BAA) par voie photochimique dans des microsystèmes. La première stratégie développée dans des puces en verre repose sur la synthèse du monolithe à l’aide d’un microscope à épifluorescence. La deuxième approche est basée sur les propriétés photochimiques d’un nouvel amorceur qui a permis de synthétiser et d’ancrer le monolithe, en une seule étape, aux parois des puces en polydiméthylsiloxane (PDMS). Une caractérisation de ce monolithe en termes de morphologie, de perméabilité, de porosité et de surface spécifique a ensuite été réalisée. Ceci a permis de démontrer le potentiel de ce monolithe pour la préconcentration.Dans un deuxième temps, une méthode de séparation par électrophorèse couplée à une détection par fluorescence a été développée sur puce en verre. Celle-ci a permis de séparer un mélange de phosphopeptides modèles fluorescents possédant différents sites et degrés de phosphorylation. Les phosphopeptides ont été détectés en moins de 2 min avec une excellente résolution (R>3) et une bonne efficacité (plateaux théoriques compris entre 11000 et 25000). Enfin, le couplage en ligne du module de préconcentration monolithique et de séparation/détection a été réalisé. Sur ce dispositif miniaturisé, une préconcentration basée sur l’IMAC-Zr4+ a ainsi été développée. L’efficacité de la capture et de l’élution des phosphopeptides a été démontrée et des facteurs de préconcentration supérieurs à 340 ont été obtenus. En conclusion, ce laboratoire sur puce ouvre des perspectives très prometteuses dans le domaine du diagnostic de pathologies dont le processus physiopathologique implique des phosphopeptides.Mots clés : laboratoire sur puce, microsystème, phosphopeptide, IMAC, monolithe, photopolymérisation, préconcentration, électrophorèse sur puce / A lab on-a-chip is a miniaturized device that integrates onto a single chip different analytical steps (preconcentration, separation, detection...) with minimal sample consumption and short analysis time. They are potentially beneficial in phosphorylated biomarker analysis for which a preconcentration step is necessary because of their low abundance in biological fluids. That's why selective enrichment methods of phosphopeptides have been developed in recent years in particular those based on solid supports like Immobilized Metal Affinity Chromatography (IMAC). Among the solid supports, organic polymer monoliths present practical advantages when used in microchips due to their ease of preparation and in situ polymerization. The aim of this work was to develop a lab-on-a-chip integrating a monolithic support for online IMAC-based preconcentration and electrophoretic separation of phosphopeptides.In the first part, we developed two innovative approaches which allowed us to synthesize, for the first time, an ethylene glycol methacrylate phosphate-co-bisacrylamide (poly (EGMP-co-BAA)) monolith by a photo-driven process in microsystems. The first monolith synthesis approach was developed in glass microchannels using an inverted epifluorescence microscope as UV-irradiation source. The second approach was based on the photochemical properties of a new initiator which allowed the simultaneous synthesis and anchorage of the monolith in native polydimethylsiloxane (PDMS) microchips. A characterization (morphology, permeability, porosity and specific surface area) of (poly (EGMP-co-BAA)) monolith was then performed which demonstrated the potential of this monolith for preconcentration.Then a glass microchip electrophoresis method coupled to a detection by fluorescence was developed to separate a mixture of phosphopeptides fluorescent models differing with the position and number of phosphorylation sites. The phosphopeptides were detected in less than 2 min with excellent resolution (R> 3) and good efficiencies ranging from 11000 to 25000 plates. Finally, an integrated microdevice was developed by combining online preconcentration based on IMAC-Zr4+ and separation/detection of phosphopeptides. The performance of this integrated microdevice to capture and to elute the phosphopeptides was demonstrated and signal enhancement factors (SEF) higher than 340 were obtained. This lab-on-a-chip device opens news perspectives for phosphoproteomic applications and the diagnostic of diseases where the pathophysiological process involves phosphopeptides

Monolithe

Préconcentration

Phosphopeptides

Microsystème

Laboratoire sur puce

Imac

Monolith

Preconcentration

Phosphopeptides

Microchips

Lab on-A-Chip

Imac

Détection électrochimique en puce microfluidique : importance des transducteurs nanocarbonés / Electrochemical detection in microfluidic devices : study of carbon-based nanomaterials as transducers

Zribi, Bacem

26 February 2016

Dans le cadre d’une thèse en cotutelle qui a démarré en Janvier 2013, j'ai développé des biopuces ultra-sensibles pour la détection de maladies infectieuses (Tuberculose et Hepatite C). Ce sujet, qui combine recherche fondamentale et recherche appliquée dans pour le diagnostic précoce de maladies, avait pour but la détection rapide d’espèces chimiques fortement diluées dans un liquide biologique. Cette détection se fait de manière électrochimique, grâce à l’utilisation des nanomatériaux carbonés innovants (feuillets de graphène, nanotubes de carbone (NTCS)) qui sont dotés d’une conductivité électronique élevée. J’intègre ces nanomatériaux par des procédés de micro/nanofabrication sur des électrodes de travail dans des cellules microfluidiques. J'ai démontré qu'en combinant un haut flux et un transducteur en NTCs qu'il est possible d'augmenter de 3 ordres de grandeur la sensibilité de détection dans la chambre fluidique (article soumis à LoC). J'ai aussi étudié par spectroscopîe d'impédance la nature du transfert des charges entre l'électrolyte et la graphène (2ème article en cours de rédaction). Mon doctorat a donc validé une technologie innovante pour les biocapteurs miniaturisés à ADN, avec un fort potentiel de valorisation, dans le domaine de la santé et de l’environnement. / As part of my thesis under joint supervision between UPS and Sfax Universities which started in January 2013, I developed ultra-sensitive biochips for the detection of infectious diseases (Tuberculosis and Hepatitis C). This subject, which combines basic and applied research for the early detection of diseases, aimed rapid detection of highly diluted chemical species such as DNA in a biological fluid. This detection is done electrochemically, through the use of innovative carbon nanomaterials (graphene layers, carbon nanotubes (NTCS)) which are provided with a high electron conductivity. I have integrated these nanomaterials by micro / nano-fabrication processes on working electrodes in microfluidic cells. I demonstrated that by combining a high flow and a that CNTs as transducer, the sensitivity of detection in the fluid chamber can be increased by 3 orders of magnitude (Article submitted to Lab on Chip journal). I also studied by impedance spectroscopy the nature of the charge transfer between the electrolyte and the graphene (2nd article being drafted). My PhD has validated an innovative technology for miniaturized biosensors DNA, with a strong development potential in the field of health and the environment.

Microfluidique

Détection électrochimique

Nanomatériaux carbonés

Adn

Lab-On-A-Chip

Electrochemical detection

Carbon nanomaterials

Dna

DEVELOPING WAX-ON-PLASTIC PLATFORMS FOR BIOANALYTICAL AND BIOMEDICAL APPLICATIONS

Qamar, Ahmad Zaman

01 December 2019

Developing microdevices on flexible material attracts scientific community to explore applications in different aspects of health and point of care diagnostics. Flexible substrates offer unique characteristics such as flexibility, stretchability, portability, low-cost, and simple fabrication. Fabrication of cost-effective paper-based analytical devices by wax printing has recently become popular using cellulose filter papers. Paper-based devices need higher temperature to form hydrophobic barrier across paper substrate, rely on large working channels (≥ 500 μm) for liquid handling, and exhibit lower efficiency (~50%) of sample mobility. Such limitations confine applications of wax-based fabrication. In this dissertation, we report printability, fidelity, and applications of wax micropatterns on polyethylene terephthalate-based substrate (PET), which is a a non-cellulosic, non-fibrous, and non-porous material. Resolution, sustainability against heat and biocompatibility was tested on wax micro-features. The patterned devices were explored for variety of applications.First, wax microwells on PET showed mouse embryonic stem cell (mESC) self-renewal or direct differentiation. Second, microfluidic flow was demonstrated on wax printed microchannels on PET which was used to develop distance-based assay. Third, fluidic properties of trinucleotide repeat sequences were investigated on wax microchannels. Fourth, multilayer wax-on-plastic device was fabricated using wax printing with hand painting of conductive materials for electrochemical immunosensing.

Lab on a chip (LOC) devices

Microfluidics

Neurodegenerative diseases

Wax printing

Wax-on-plastic platforms

Sequence Specific Concentration and Labeling of Bacterial Plasmids for Future Use in Detection of Drug-Resistant Sepsis Cases Without Amplification

Hanson, Robert L.

25 June 2021

Rapidly diagnosing the precise drug resistance present in sepsis-inducing bacteria is a continuing need to maintain the efficacy of our medical systems. Diagnostics currently being developed for such scenarios are either sensitive or rapid, but not both. Sequence-specific single DNA molecule analysis could fill this gap if it could be adapted to work on smaller targets, similar to those produced by classical biological methods. In this work, I demonstrate that immobilized ssDNA in the appropriate hybridization buffer can rapidly pull its complementary sequence out of solution. I also demonstrate that such systems in a microfluidic chip can be used to capture bacterial plasmids as a step toward subsequent multiplexed analysis. Finally, I demonstrate that a 120 bp double stranded polynucleotide with an overhanging single stranded 25 bp probe sequence can be modified with multiple fluorophores and used to label captured targets in a sequence-specific manner. This system shows that it is possible to label bacterial plasmids in a manner that can bridge the technological gap between single molecule counting and small oligonucleotide targets. Such a system can achieve lower limits of detection for clinically relevant samples while maintaining rapid processing times.

Microfluidics

DNA

hybridization

sepsis

lab on a chip

drug resistance

Physical Sciences and Mathematics

Mise au point d’un laboratoire sur puce pour la détection de cellules eucaryotes par des capteurs à magnétorésistance géante / Development of a lab on a chip for the detection of eukaryotic cells by giant magnetoresistance sensors

Giraud, Manon

21 November 2019

Les tests « in vitro » permettent d’établir près de 70% des diagnostics et leur développement pour une utilisation au plus près du patient apparaît donc comme un enjeu majeur de santé publique. Dans ce contexte, les critères ASSURED (« Affordable, Sensitive, Specific, User-friendly, Rapid and robust, Equipment-free and Deliverable to end-users ») a été défini par l’organisation mondiale de la santé pour que les chercheurs développent des outils de diagnostic dits « Point of Care » utilisables par le plus grand nombre. Avec l’essor de la microfluidique, la gamme des dispositifs possibles s'est élargie et des biocapteurs intégrés ont été développés, transformant le signal biologique d’une reconnaissance d’un biomarqueur par une sonde biologique en un signal optique, électrochimique, mécanique ou encore magnétique. Comme les milieux biologiques sont en grande majorité amagnétiques, les capteurs magnétiques ne sont pas affectés par l’utilisation de matrices biologiques complexes comme peuvent l’être les mesures optiques ou électrochimiques. De plus ces capteurs sont faciles à produire et intégrables dans les puces microfluidiques. Cette thèse a pour objectifs de concevoir un outil de diagnostic in vitro basé sur des capteurs à magnétorésistance géante et de tester ses performances. Cette étude a été réalisée en utilisant une lignée cellulaire de myélome murin. Les cellules sont marquées spécifiquement par des particules magnétiques fonctionnalisées par des anticorps dirigés contre un de leurs antigènes et sont passées dans le canal microfluidique au-dessus des capteurs. Cette méthode de détection dynamique permet de compter les objets magnétiques un par un. La difficulté réside dans la distinction des signaux spécifiques provenant des cellules marquées des signaux faux positifs induits par les billes restant en solution. Deux types de dispositifs ont été conçus dans cette thèse pour lever ce verrou. Le premier possède une couche inerte de séparation de quelques micromètres entre les capteurs GMR et le canal qui permet de supprimer les signaux des billes isolées. Le second dispositif, qui a des capteurs à la fois au-dessus et au-dessous du canal microfluidique, permet une double détection simultanée de chaque objet magnétique. Il est ainsi possible de connaître le nombre de billes qui les marquent et de déterminer s’il s’agit d’un agrégat de billes ou d’un objet biologique. / The « in vitro » tests are requested for the establishment of nearly 70% of diagnoses and their development for on-site detection therefore appears to be a major public health issue. In this context, the ASSURED criterion (« Affordable, Sensitive, Specific, User-friendly, User-friendly, Rapid and robust, Equipment-free and Deliverable to end-users ») has been defined by the World Health Organization to encourage researchers to develop diagnostic tools called « Point of Care » that can be widely used.With the rise of microfluidics, the range of possible devices has broadened and integrated biosensors have been developed, transforming the biological signal from a biomarker recognition by a biological probe into an optical, electrochemical, mechanical or magnetic signal. As biological environments are largely non-magnetic, magnetic sensors are not affected by the use of complex biological matrices as are optical or electrochemical measurements. In addition, these sensors are easy to produce and can be integrated into microfluidic chips. The objectives of this thesis are to design a diagnostic tool in vitro based on giant magnetoresistance sensors and to test its performance. Its development was carried out using a murine myeloma cell line. The cells are specifically labeled by magnetic particles functionalized by antibodies directed against one of their antigens and flown in the microfluidic channel above the sensors. This dynamic detection method allows magnetic objects to be counted one by one. The challenge is to distinguish the signals coming from the labeled cells from those of the beads remaining in solution. In order to address this problem, two labs on chips are developed in this thesis. In a first device, an inner layer of a few micrometers separates the sensors from the channel which allows to suppress the signals of the isolated beads. The second device has sensors both above and below the microfluidic channel and can measure the number of beads corresponding to each doubly detected object which can thus be identified (aggregates or biological objects).

Biocapteur

Diagnostic

Laboratoire sur puce

Magnétorésistance géante

Microfluidique

Biosensor

Diagnostic

Giant magnetoresistance

Lab on a chip

Microfluidics