DNAzyme Crosslinked Polyacrylamide Hydrogels for the Colorimetric Detection of E. coli / Hydrogels For Colorimetric E. coli Detection

Mann, Hannah

January 2024

Escherichia coli (E. coli) is a gram-negative bacteria found in the intestinal system of humans that can also contaminate food, drinking water, as well as lakes and rivers. While not all strains are pathogenic, some including O157:H7 can cause severe illness. Conventional methods of detecting E. coli contamination in water samples often have limitations for on-site testing applications, which can include their slow detection time or need for expensive laboratory equipment. While several fluorescent biosensors for the detection of E. coli have been developed in the Didar lab, there is increased interest in colourimetric biosensors whose signal can be interpreted with the naked eye. This thesis will describe the development and performance of a hydrogel biosensor, that is made of polyacrylamide chains crosslinked by an E. coli detecting Deoxyribozyme (DNAzyme) and its substrate. In the presence of E. coli, the DNAzyme cleaves its substrate and crosslinking breaks down, resulting in the visible dissolution of the hydrogel. Paired with the use of bacteriophage induced cell lysis to amplify the target protein, detection sensitivity to the order of 10^1 CFU/mL has been achieved using this platform with an incubation time of 18 hours. A convolutional neural network (CNN) trained on optical images of the platform was able to classify samples as contaminated or uncontaminated with a validation accuracy of over 93%. / Thesis / Master of Applied Science (MASc) / Microbial contamination of water sources including surface water, groundwater, and drinking water can pose risks to human health. One bacterial species that can sometimes contaminate these sources is Escherichia coli (E. coli). To determine if E. coli is present in a water sample, it often needs to be sent to a laboratory for testing, which can be time consuming and inconvenient. Therefore, researchers are working to develop new sensors that are able to detect E. coli from water samples, ideally being simple enough to use that testing could be done right away and without sending the sample to another location. In this research project, we have developed a new biosensor that can detect E. coli in water samples. To use the sensor, a water sample is added onto a small red gel in a tube, and this gel breaks apart if E. coli is present in the sample.

Water Contamination

Colorimetric Sensor

E. coli Detection

DNAzyme

Xanthene-based Artificial Enzymes And A Dimeric Calixpyrrole As A Chromogenic Chemosensor

Saki, Neslihan

01 September 2004

This thesis covers the combination of two seperate work accomplished during the throughout the study. In the first part of the study, xanthene based artificial enzymes were synthesized, and kinetic hydrolysis studies done. Artificial enzyme design is an active field of supramolecular chemistry and metalloenzymes are attractive targets in such studies. Enzymatic catalysis is essentially a &lsquo / multifuctional&rsquo / catalysis. As part of our work, we designed and synthesized three novel xanthene derivatives. All three model contain Zn(II) in their active sites. Using the model substrate p-nitrophenyl acetate, we showed that the bifunctional model is at least an order of magnitude more active in catalyzing the hydrolysis of the substrate. Compared to the uncatalyzed hydrolysis reaction of the p-nitrophenyl ester at pH 7.0, the bifunctional model complex showed a 5714-fold rate acceleration. The second part of the thesis involves the design of a dimeric calixpyrrole as a chromogenic chemosensor. Anions are involved in a large number of biological processes and there is an interest in developing molecular sensors for these charged species. The calixpyrroles are a class of old but new heterocalixarene analogues that show considerable promise in the area of anion sensing. In this work, we have designed, synthesized and characterized a calixpyrrole-dimer anion sensor for its anion binding strength. The dimer forms stable complexes with p-nitrophenolate ion. This formed complex is used as a colorimetric sensor by displacing the chromogenic anion with the addition of various anions. like fluoride and acetate. The receptor shows strong affinity and high selectivity for fluoride anion, and also show reasonable affinity toward acetate. Thus, effective optical sensing of biochemically relevant these anions is accomplished using the calixpyrrole dimer.

QD Biochemistry 415-436

Síntese e caracterização de nanopartículas magnéticas de ferrita de níquel para detecção de ácido ascórbico e peróxido de hidrogênio

Fracari, Tiago Ost

January 2018

Neste estudo apresenta-se a síntese de duas amostras de nanopartículas de ferrita de níquel, denominadas C-NiFe2O4 e NiFe2O4, através de um método simples, de baixo custo e ambientalmente amigável. Estudos morfológicos, estruturais, eletrônicos, ópticos e magnéticos foram realizados com o intuito de caracterizar as propriedades desses materiais para que possibilitassem, além de maior grau de conhecimento, sua aplicação como sensores colorimétricos para detecção de ácido ascórbico e peróxido de hidrogênio. Mediante a análise térmica dos precursores, foi possível determinar os intervalos de temperatura de decomposição, assim como a temperatura ótima de formação das nanopartículas. A amostra NiFe2O4 é ferromagnética e corresponde a uma fase cúbica de espinélio inverso. Os dados de difração de raios X, espectroscopia Mössbauer e o modelo iônico sugerem a presença de um certo grau de substituição, possuindo em sua estrutura um cátion divalente como agente dopante. As nanopartículas de C-NiFe2O4 foram utilizadas como catalisador na oxidação do 3,3',5,5'-tetrametilbenzidina (TMB) em meio ácido para formar uma solução azul sem adição de outro reagente. Como resultado foi utilizado como sensor colorimétrico para detecção de ácido ascórbico, visto que este reduz o complexo de transferência de carga, TMBOX, novamente para TMB. A calibração analítica apresentou uma faixa linear entre 1-20 μM para a concentração de ácido ascórbico, com limite de detecção (3/m) de 0,93 μM. A determinação em suplementos de vitamina C através do método de adição de padrão mostrou a eficiência do sensor para detectar ácido ascórbico em amostras reais. Já a amostra de NiFe2O4 demonstrou atividade catalítica semelhante as peroxidases naturais, oxidando o TMB na presença de H2O2 para formar TMBOX, que dá coloração azul a solução. Dessa forma, NiFe2O4 foi utilizado em um sensor colorimétrico para detecção de H2O2 e a calibração analítica revelou duas faixas lineares, uma entre 2,28 - 28,60 μM e a outra entre 28,60 μM - 114,20 μM. O limite de detecção (3/m) foi de 1,94 μM. Ambos os métodos apresentaram boa repetibilidade, com coeficiente de variação de 3,5% e 4% respectivamente. / This study presents the synthesis of two samples of nickel ferrite nanoparticles, termed C-NiFe2O4 and NiFe2O4, through a simple, low cost and environmentally friendly method. Morphological, structural, electronic, optical and magnetic studies were carried out with the aim of characterizing the properties of these materials, which allowed the application of colorimetric sensors for the detection of ascorbic acid and hydrogen peroxide. Through the thermal analysis of the precursors, it was possible to determine the decomposition temperature ranges, as well as the optimum temperature of formation of the nanoparticles. The sample NiFe2O4 is ferromagnetic and corresponds to a cubic phase of inverse spinel. The X-ray diffraction data, Mössbauer spectroscopy and the ionic model suggest the presence of a certain degree of substitution, having in its structure a divalent cation as a doping agent. The C-NiFe2O4 nanoparticles were used as catalysts in the oxidation of 3,3',5,5'-tetramethylbenzidine (TMB) in acidic medium to form a blue solution without addition of another reagent. As a result, it was used as a colorimetric sensor for the detection of ascorbic acid, as it reduces the charge transfer complex, TMBOX, again to TMB. The analytical calibration showed a linear range between 1-20 μM for the concentration of ascorbic acid, with a detection limit (3 /m) of 0.93 μM. The determination of vitamin C supplements using the standard addition method showed the efficiency of the sensor to detect ascorbic acid in actual samples. Already NiFe2O4 sample demonstrated catalytic activity similar to natural peroxidases, oxidizing the TMB in the presence of H2O2 to form TMBOX, which gives blue coloration to the solution. Thus, NiFe2O4 was used in a colorimetric sensor to detect H2O2, and the analytical calibration revealed two linear ranges, one between 2.28 - 28.60 μM and the other between 28.60 μM - 114.20 μM. The detection limit (3 /m) was 1.94 μM. Both methods presented good repeatability, with a coefficient of variation of 3.5% and 4% respectively.

Nanoparticulas

Ácido ascórbico

Peróxido de hidrogênio

Nickel ferrite nanoparticles

Hydrogen peroxide

Ascorbic acid

Colorimetric sensor

Síntese e caracterização de nanopartículas magnéticas de ferrita de níquel para detecção de ácido ascórbico e peróxido de hidrogênio

Fracari, Tiago Ost

January 2018

Neste estudo apresenta-se a síntese de duas amostras de nanopartículas de ferrita de níquel, denominadas C-NiFe2O4 e NiFe2O4, através de um método simples, de baixo custo e ambientalmente amigável. Estudos morfológicos, estruturais, eletrônicos, ópticos e magnéticos foram realizados com o intuito de caracterizar as propriedades desses materiais para que possibilitassem, além de maior grau de conhecimento, sua aplicação como sensores colorimétricos para detecção de ácido ascórbico e peróxido de hidrogênio. Mediante a análise térmica dos precursores, foi possível determinar os intervalos de temperatura de decomposição, assim como a temperatura ótima de formação das nanopartículas. A amostra NiFe2O4 é ferromagnética e corresponde a uma fase cúbica de espinélio inverso. Os dados de difração de raios X, espectroscopia Mössbauer e o modelo iônico sugerem a presença de um certo grau de substituição, possuindo em sua estrutura um cátion divalente como agente dopante. As nanopartículas de C-NiFe2O4 foram utilizadas como catalisador na oxidação do 3,3',5,5'-tetrametilbenzidina (TMB) em meio ácido para formar uma solução azul sem adição de outro reagente. Como resultado foi utilizado como sensor colorimétrico para detecção de ácido ascórbico, visto que este reduz o complexo de transferência de carga, TMBOX, novamente para TMB. A calibração analítica apresentou uma faixa linear entre 1-20 μM para a concentração de ácido ascórbico, com limite de detecção (3/m) de 0,93 μM. A determinação em suplementos de vitamina C através do método de adição de padrão mostrou a eficiência do sensor para detectar ácido ascórbico em amostras reais. Já a amostra de NiFe2O4 demonstrou atividade catalítica semelhante as peroxidases naturais, oxidando o TMB na presença de H2O2 para formar TMBOX, que dá coloração azul a solução. Dessa forma, NiFe2O4 foi utilizado em um sensor colorimétrico para detecção de H2O2 e a calibração analítica revelou duas faixas lineares, uma entre 2,28 - 28,60 μM e a outra entre 28,60 μM - 114,20 μM. O limite de detecção (3/m) foi de 1,94 μM. Ambos os métodos apresentaram boa repetibilidade, com coeficiente de variação de 3,5% e 4% respectivamente. / This study presents the synthesis of two samples of nickel ferrite nanoparticles, termed C-NiFe2O4 and NiFe2O4, through a simple, low cost and environmentally friendly method. Morphological, structural, electronic, optical and magnetic studies were carried out with the aim of characterizing the properties of these materials, which allowed the application of colorimetric sensors for the detection of ascorbic acid and hydrogen peroxide. Through the thermal analysis of the precursors, it was possible to determine the decomposition temperature ranges, as well as the optimum temperature of formation of the nanoparticles. The sample NiFe2O4 is ferromagnetic and corresponds to a cubic phase of inverse spinel. The X-ray diffraction data, Mössbauer spectroscopy and the ionic model suggest the presence of a certain degree of substitution, having in its structure a divalent cation as a doping agent. The C-NiFe2O4 nanoparticles were used as catalysts in the oxidation of 3,3',5,5'-tetramethylbenzidine (TMB) in acidic medium to form a blue solution without addition of another reagent. As a result, it was used as a colorimetric sensor for the detection of ascorbic acid, as it reduces the charge transfer complex, TMBOX, again to TMB. The analytical calibration showed a linear range between 1-20 μM for the concentration of ascorbic acid, with a detection limit (3 /m) of 0.93 μM. The determination of vitamin C supplements using the standard addition method showed the efficiency of the sensor to detect ascorbic acid in actual samples. Already NiFe2O4 sample demonstrated catalytic activity similar to natural peroxidases, oxidizing the TMB in the presence of H2O2 to form TMBOX, which gives blue coloration to the solution. Thus, NiFe2O4 was used in a colorimetric sensor to detect H2O2, and the analytical calibration revealed two linear ranges, one between 2.28 - 28.60 μM and the other between 28.60 μM - 114.20 μM. The detection limit (3 /m) was 1.94 μM. Both methods presented good repeatability, with a coefficient of variation of 3.5% and 4% respectively.

Nanoparticulas

Ácido ascórbico

Peróxido de hidrogênio

Nickel ferrite nanoparticles

Hydrogen peroxide

Ascorbic acid

Colorimetric sensor

A Novel Handheld Real-time Carbon Dioxide Analyzer for Health and Environmental Applications

January 2014

abstract: The accurate and fast determination of carbon dioxide (CO2) levels is critical for many health and environmental applications. For example, the analysis of CO2 levels in exhaled breath allows for the evaluation of systemic metabolism, perfusion, and ventilation, and provides the doctors and patients with a non-invasive and simple method to predict the presence and severity of asthma, and Chronic Obstructive Pulmonary Disease (COPD). Similarly, the monitoring of CO2 levels in the atmosphere allows for assessment of indoor air quality (IAQ) as the indoor CO2 levels have been proved to be associated with increased prevalence of certain mucous membrane and respiratory sick building syndrome (SBS) symptoms. A pocket-sized CO2 analyzer has been developed for real-time analysis of breath CO2 and environmental CO2. This CO2 analyzer is designed to comprise two key components including a fluidic system for efficient gas sample delivery and a colorimetric detection unit integrated into the fluidic system. The CO2 levels in the gas samples are determined by a disposable colorimetric sensor chip. The sensor chip is a novel composite based sensor that has been optimized to provide fast and reversible response to CO2 over a wide concentration range, covering the needs of both environmental and health applications. The sensor is immune to the presence of various interfering gases in ambient or expired air. The performance of the sensor in real-time breath-by-breath analysis has also been validated by a commercial CO2 detector. Furthermore, a 3D model was created to simulate fluid dynamics of breath and chemical reactions for CO2 assessment to achieve overall understanding of the breath CO2 detection process and further optimization of the device. / Dissertation/Thesis / Ph.D. Chemical Engineering 2014

Chemical engineering

CO2 detection

colorimetric sensor

disease diagnosis

environmental

pocket-sized

wireless

Síntese e caracterização de nanopartículas magnéticas de ferrita de níquel para detecção de ácido ascórbico e peróxido de hidrogênio

Fracari, Tiago Ost

January 2018

Neste estudo apresenta-se a síntese de duas amostras de nanopartículas de ferrita de níquel, denominadas C-NiFe2O4 e NiFe2O4, através de um método simples, de baixo custo e ambientalmente amigável. Estudos morfológicos, estruturais, eletrônicos, ópticos e magnéticos foram realizados com o intuito de caracterizar as propriedades desses materiais para que possibilitassem, além de maior grau de conhecimento, sua aplicação como sensores colorimétricos para detecção de ácido ascórbico e peróxido de hidrogênio. Mediante a análise térmica dos precursores, foi possível determinar os intervalos de temperatura de decomposição, assim como a temperatura ótima de formação das nanopartículas. A amostra NiFe2O4 é ferromagnética e corresponde a uma fase cúbica de espinélio inverso. Os dados de difração de raios X, espectroscopia Mössbauer e o modelo iônico sugerem a presença de um certo grau de substituição, possuindo em sua estrutura um cátion divalente como agente dopante. As nanopartículas de C-NiFe2O4 foram utilizadas como catalisador na oxidação do 3,3',5,5'-tetrametilbenzidina (TMB) em meio ácido para formar uma solução azul sem adição de outro reagente. Como resultado foi utilizado como sensor colorimétrico para detecção de ácido ascórbico, visto que este reduz o complexo de transferência de carga, TMBOX, novamente para TMB. A calibração analítica apresentou uma faixa linear entre 1-20 μM para a concentração de ácido ascórbico, com limite de detecção (3/m) de 0,93 μM. A determinação em suplementos de vitamina C através do método de adição de padrão mostrou a eficiência do sensor para detectar ácido ascórbico em amostras reais. Já a amostra de NiFe2O4 demonstrou atividade catalítica semelhante as peroxidases naturais, oxidando o TMB na presença de H2O2 para formar TMBOX, que dá coloração azul a solução. Dessa forma, NiFe2O4 foi utilizado em um sensor colorimétrico para detecção de H2O2 e a calibração analítica revelou duas faixas lineares, uma entre 2,28 - 28,60 μM e a outra entre 28,60 μM - 114,20 μM. O limite de detecção (3/m) foi de 1,94 μM. Ambos os métodos apresentaram boa repetibilidade, com coeficiente de variação de 3,5% e 4% respectivamente. / This study presents the synthesis of two samples of nickel ferrite nanoparticles, termed C-NiFe2O4 and NiFe2O4, through a simple, low cost and environmentally friendly method. Morphological, structural, electronic, optical and magnetic studies were carried out with the aim of characterizing the properties of these materials, which allowed the application of colorimetric sensors for the detection of ascorbic acid and hydrogen peroxide. Through the thermal analysis of the precursors, it was possible to determine the decomposition temperature ranges, as well as the optimum temperature of formation of the nanoparticles. The sample NiFe2O4 is ferromagnetic and corresponds to a cubic phase of inverse spinel. The X-ray diffraction data, Mössbauer spectroscopy and the ionic model suggest the presence of a certain degree of substitution, having in its structure a divalent cation as a doping agent. The C-NiFe2O4 nanoparticles were used as catalysts in the oxidation of 3,3',5,5'-tetramethylbenzidine (TMB) in acidic medium to form a blue solution without addition of another reagent. As a result, it was used as a colorimetric sensor for the detection of ascorbic acid, as it reduces the charge transfer complex, TMBOX, again to TMB. The analytical calibration showed a linear range between 1-20 μM for the concentration of ascorbic acid, with a detection limit (3 /m) of 0.93 μM. The determination of vitamin C supplements using the standard addition method showed the efficiency of the sensor to detect ascorbic acid in actual samples. Already NiFe2O4 sample demonstrated catalytic activity similar to natural peroxidases, oxidizing the TMB in the presence of H2O2 to form TMBOX, which gives blue coloration to the solution. Thus, NiFe2O4 was used in a colorimetric sensor to detect H2O2, and the analytical calibration revealed two linear ranges, one between 2.28 - 28.60 μM and the other between 28.60 μM - 114.20 μM. The detection limit (3 /m) was 1.94 μM. Both methods presented good repeatability, with a coefficient of variation of 3.5% and 4% respectively.

Nanoparticulas

Ácido ascórbico

Peróxido de hidrogênio

Nickel ferrite nanoparticles

Hydrogen peroxide

Ascorbic acid

Colorimetric sensor

Carbon Nanotube- and Gold Nanoparticle-Based Materials For Electrochemical and Colorimetric Sensing Applications

Paudyal, Janak, 9255967

09 November 2016

Carbon nanotubes (CNTs) and gold nanoparticles (AuNPs) are widely used for sensing applications due to their distinctive electrical and optical properties, and we have explored the development of methods that enable the incorporation of these nanomaterials into new and improved sensing devices. As a means for fabricating simple, low-cost and fast detection platforms for various applications, we have developed paper-based electrochemical detection platforms based on CNTs or platinum nanoparticle (PtNP)-CNT composite materials. We describe the use of a paper-based, low density, a three-dimensional thin film of interconnected CNTs as an electrode material. We studied the electrochemical properties of these paper-based CNT electrodes and demonstrated their use as an electrochemical sensor for the sensitive detection of guanine-based nucleotides. We further describe the functionalization of this paper-based electrode by fabricating a PtNP-SWCNT hybrid film via a vacuum filtration-based method. The interconnected PtNP structure formed on top of the CNT-coated paper was directly used as an electrocatalyst for methanol oxidation. Compared to paper-based PtNP-SWCNT hybrid films formed by electrochemical deposition, hybrid films formed by vacuum filtration showed a higher electrochemical surface area and enhanced electrocatalytic response to methanol oxidation. We have also developed methods based around DNA-modified AuNPs, which offer an excellent colorimetric platform for target detection. The DNA density on the surface of modified AuNPs affects enzymatic activity, colloidal stability of AuNPs, the orientation of the probe DNA and its hybridization efficiency. The combination of all these factors ultimately dictates the reaction time and sensitivity of colorimetric assays. We demonstrate the use of DTT as a modulator to control DNA surface coverage on the surface of AuNPs. Using this DTT treatment and a novel probe for exonuclease III activity, we have developed a colorimetric assay based on DTT-treated, DNA-modified AuNPs that can achieve more sensitive and rapid detection of DNA and enzymes relative to existing sensor platforms.

Paper-based sensor

Guanine

Platinum nanoparticle

Gold Nanoparticle

Carbon Nanotube

Methanol

DNA

Electrochemical sensor

Colorimetric Sensor

Analytical Chemistry

Materials Chemistry

DEVELOPMENT OF SMART CONTACT LENS TO MONITOR EYE CONDITIONS

Seul Ah Lee (17591811)

11 December 2023

<p>  </p> <p>In this study, we present advancements in smart contact lenses, highlighting their potential as minimally or non-invasive diagnostic and drug delivery platforms. The eyes, rich in physiological and diagnostic data, make contact lens sensors an effective tool for disease diagnosis. These sensors, particularly smart contact lenses, can measure various biomolecules like glucose, urea, ascorbate, and electrolytes (Na+, K+, Cl-, HCO3-) in ocular fluids, along with physical biomarkers such as movement of the eye, intraocular pressure (IOP) and ocular surface temperature (OST).</p> <p>The study explores the use of continuous, non-invasive contact lens sensors in clinical or point-of-care settings. Although promising, their practical application is hindered by the developmental stage of the field. This thesis addresses these challenges by examining the integration of contact lens sensors, covering their working principle, fabrication, sensitivity, and readout mechanisms, with a focus on monitoring glaucoma and eye health conditions like dry eye syndrome and inflammation.</p> <p>Our design adapts these sensors to fit various corneal curvatures and thicknesses. The lenses can visually indicate IOP through microfluidic channels' mechanical deformation under ambulatory conditions. We also introduce a colorimetric hydrogel tear fluid sensor that detects pH, electrolytes, and ocular surface temperature, indicating conditions like dry eye disease and inflammation.</p> <p>The evaluation of these contact lens sensors includes in vivo/vitro biocompatibility, ex vivo functionality studies, and in vivo safety assessments. Our comprehensive analysis aims to enhance the practicality and effectiveness of smart contact lenses in ophthalmic diagnostics and therapeutics.</p>

Biomaterials

Biomechanical engineering

Biomedical imaging

Medical devices

colorimetric sensor systems

hydrogel

contact lens sensor

wearable devices and sensors

tear fluid sensor

Conception et caractérisation d'une puce colorimétrique pour la détection des allergènes / Design and characterization of colorimetric micro-chip for the detection of allergens

El Idrissi, Sana

07 January 2015

Cette thèse traite un sujet pluridisciplinaire, la conception d’un prototype de micro-capteur biologique pour la détection des anticorps de patients susceptibles d'être allergiques.Elle a pour objectif la miniaturisation de la méthode ELISA pour « Enzyme Linked Immune Sorbent Assay » en concevant en « full-custom », avec une technologie CMOS APS, un capteur colorimétrique. Ce capteur est posé en dessous un système micro fluidique contenant l’échantillon biologique à tester, le tout est illuminé via une fibre optique. Le détecteur capte la lumière qui a traversé le micro-tube contenant l’échantillon. Les courants photoniques induits sont liés à la concentration et la coloration de la solution. Le virage colorimétrique de la réaction enzymatique, due à la présence des anticorps dans le sérum, et l’évaluation quantitative de la concentration seront déterminée par la mesure de ces photo-courants. Le capteur pourrait contenir une matrice de 20x20 pixels de détecteurs de couleur ainsi que leur électronique de lecture et de commande. Pour des raisons de coûts, nous avons validé le procédé à l’aide d’une matrice de 4x4 pixels de détecteur de couleur. La réalisation du circuit a été suivie par une caractérisation électrique et colorimétrique. La caractérisation électrique a permis de valider le fonctionnement du bloc de commande du circuit ainsi que celui du pixel (l’électronique de lecture, BDJ). Les résultats de mesures concordent avec ceux de simulations. La caractérisation colorimétrique consiste à mesurer le virage colorimétrique de deux solutions différentes. Les mesures ont pu montrer que notre capteur est plus sensible que le spectromètre utilisé pour mesurer la concentration des deux solutions. Ainsi ce travail de recherche a contribué à la miniaturisation d’une bio-puce colorimétrique dédiée aux tests immunologiques basée sur la méthode ELISA. / This PhD treats a multidisciplinary subject based on the design of a biological micro-sensor prototype for the detection of antibodies of patients susceptible to be allergic.The goal has been the miniaturization of the ELISA "Enzyme Linked Immune Sorbent Assay" method, designing in integrated full-custom colorimetric sensor with a CMOS APS technology. This sensor is installed below a microfluidic system containing the biological test sample, the whole is illuminated via an optical fiber. The sensor detects the light passed through the micro reservoir containing the sample, the induced photo-currents is related to the concentration of the solution. The color change of the enzyme reaction due to the presence of antibodies in the serum, and the quantitative evaluation of the concentration will be determined by the measurement of the induced photo-currents. The sensor may contain a matrix of 20x20 color detector pixels and their reading and control electronics. For cost reasons, we validated the method using a matrix of 4 x 4 pixels of color detectors.The design of electrical device was followed by a colorimetric and electrical characterizations. The latter was used to validate the operation of the control block of the circuit as well as that of the pixel (readout electronics, BDJ). The results brought by measurements are in good agreement with those obtained through simulations. The colorimetric characterization consists in measuring the intensity of the color of two different solutions of different colors. These measurements have shown that our sensor is more sensitive than a spectrometer. Therefore, this research work has contributed to the miniaturization of a colorimetric sensor and its electronic part for the Immunoassay based on the ELISA method.

Capteur CMOS APS

Micro-Électronique

Micro fluidique

Test immunologique

Biological micro-sensor prototype

Colorimetric sensor

537.62

Multi-capteurs chimiques de chloramines et de chloroforme à transduction optique. Application à la surveillance de la qualité de l’air dans les piscines / Multi-chemical sensor for the optical detection of chloramines and chloroform. Application for monitoring the air quality in pools

Nguyen, Trung Hieu

04 February 2014

Le chlore est largement utilisé pour ses propriétés bactéricides dans les piscines. Dans les eaux de piscine, le chlore réagit avec les matières azotées et carbonées générées par l’activité humaine (sueur, salive, urine, peau) pour former divers composés toxiques tels que la monochloramine (NH2Cl), la dichloramine (NHCl2), le trichlorure d'azote (NCl3), le chloroforme (CHCl3), etc… qui se retrouvent dans l’atmosphère. La détection et la quantification de ces composés volatils à des teneurs ppb (partie par milliard) est un réel besoin afin de contrôler la qualité de l’air des piscines. Cependant il n’existe pas à ce jour des appareils à la fois sensibles et peu coûteux.L’objectif de ce travail de thèse est d’élaborer des capteurs chimiques colorimétriques, sensibles, sélectifs et peu coûteux de la monochloramine, du trichlorure d’azote et du chloroforme. Dans ce but, nous avons mis au point des capteurs chimiques réalisés à partir de matrices nanoporeuses de silicate dopée des réactifs. Ainsi le capteur de NCl3 dopé de NaI et d’amylose permet de mesurer de faibles teneurs de NCl3 (5 ppb à 180 ppb) dans les atmosphères humides (50-80% HR) des piscines. Grâce au changement rapide de couleur, de transparent à rose-violet, visible à l’œil nu, le capteur de NCl3 permet de surveiller la qualité de l’air dans les piscines. Le capteur sélectif de NH2Cl est basé sur la réaction de Berthelot. La matrice de silicate nanoporeuse dopée de nitroprussiate de sodium et de phénol en milieu alcalin, initialement transparente, devient bleue lors d’une exposition à NH2Cl gazeux. Ce capteur permet de détecter NH2Cl dans la gamme de 60 à 250 ppb dans une atmosphère très humide (≈ 80%). Utilisé pour la sonder la qualité des eaux de piscine, il permet de mesurer NH2Cl dans l’eau avec une limite de détection de 0,1 µmol•L-1. Une étude préliminaire de la détection de CHCl3 a également été entreprise pour déterminer les molécules-sonde aptes à réagir avec le chloroforme en formant des produits colorés. Les réactifs de la réaction de Fujiwara ont été sélectionnés. L’étude de la réactivité de la 2,2’-bipyridine en solution en présence d’une base forte a permis de mettre en évidence la formation simultanée de deux composés colorés, dont la formation dépend de la nature de l’environnement réactionnel. / In swimming-pools, chlorine is used as a disinfectant to minimize the risk to users from microbial contaminants. In water, chlorine reacts with nitrogen compounds generated by human activity like saliva, sweat, urine and skin, leading to the formation of toxic compounds, such as monochloramine (NH2Cl), dichloramine (NHCl2), nitrogen trichloride (NCl3), chloroform (CHCl3), etc… The detection and the quantification of these volatile compounds at ppb level (part per billion) is an important and significant challenge to be able to monitor the air quality in swimming pool. Or, there is currently no commercially available and low-cost system which can instantaneously measure at ppb concentrations.The aim of this research is to develop a cheap, sensitive and selective chemical and colorimetric sensors of monochloramine, nitrogen trichloride and chloroform. For this purpose, we developed chemical sensors based on the use of nanoporous silicate matrices doped with probe-molecules. The NCl3 sensor doped with NaI and amylose can detect NCl3 at ppb level (5 ppb – 180 ppb) in humid atmospheres (from 50% to 80% relative humidity) at ambient pool temperatures. Due to the fast change of color, visible with naked eyes, these sensors can be used to detect peaks of pollution and to monitor the air quality of indoor pools. The NH2Cl selective sensor is based on the Berthelot reaction. The nanoporous silicate matrices doped with sodium nitroprusside and phenol in an alkaline medium, turn from transparent to blue upon exposure to gaseous NH2Cl. This sensor can detect NH2Cl in the range from 60 to 250 ppb in a very humid atmosphere (≈ 80%). Used to probe the quality of pool water, this sensor can detect NH2Cl in water with a detection limit of 0,1 µmol•L-1. A preliminary study of the CHCl3 detection was also conducted to identify probe-molecules capable of reacting with chloroform to form colored products. The reagents of the Fujiwara reaction were selected. The study of the 2,2’-bipyridine reactivity in solution in the presence of a strong base allowed highlighting the simultaneous formation of two colored compounds, whose formation depends on the nature of the reaction environment.

Matrice nanoporeuse

Capteur colorimétrique

Monochloramine

Trichlorure d’azote

Chloroforme

Ion iodure

Amylose

Réaction de Berthelot

Réaction de Fujiwara

Nanoporous matrices

Colorimetric sensor

Monochloramine

Nitrogen trichloride

Chloroform

Iodide ion

Berthelot reaction

Fujiwara reaction