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Stabilization of Horseradish Peroxidase Using Epoxy Novolac Resins for Applications with Microfluidic Paper-Based Analytical DevicesChaplan, Cory A. 01 June 2014 (has links)
Microfluidic paper-based analytical devices (microPADs) are an emerging platform for point-of-care diagnostic tests for use by untrained users with potential applications in healthcare, environmental monitoring, and food safety. These devices can be developed for a multitude of different tests, many of which employ enzymes as catalysts. Without specialized treatment, some enzymes tend to lose their activity when stored on microPADs within 48 hours, which is a major hurdle for taking these types of devices out of the laboratory and into the real world. This work focused on the development of simple methods for stabilizing enzymes by applying polymers to chromatography paper. The longterm stabilization was exlored and SU-8 of various concentrations was found to stabilize horseradish peroxidase for times in excess of two weeks. A variety of microPAD fabrications, enzyme dispensing methods, and substrate delivery techniques were explored.
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Platforms and Molecular Mechanisms for Improving Signal Transduction and Signal Enhancement in Multi-step Point-Of-Care DiagnosticsKaleb M. Byers (11192533) 28 July 2021 (has links)
<p>Swift recognition of
disease-causing pathogens at the point-of-care enables life-saving treatment
and infection control. However, current rapid diagnostic devices often fail to
detect the low concentrations of pathogens present in the early stages of
infection, causing delayed and even incorrect treatments. Rapid diagnostics
that require multiple steps and/or elevated temperatures to perform have a
number of barriers to use at the point-of-care and in the field, and despite
efforts to simplify these platforms for ease of use, many still require
diagnostic-specific training for the healthcare professionals who use them.
Most nucleic acid amplification assays require hours to perform in a sterile
laboratory setting that may be still more hours from a patient’s bedside or not
at all feasible for transport in remote or low-resourced areas. The cold-chain
storage of reagents, multistep sample preparation, and costly instrumentation
required to analyze samples has prohibited many nucleic acid detection and
antibody-based assays from reaching the point-of-care. There remains a critical
need to bring rapid and accessible pathogen identification technologies that
determine disease status and ensure effective treatment out of the laboratory.</p>
<p>Paper-based diagnostics have emerged as a portable platform for antigen
and nucleic acid detection of pathogens but are often limited by their
imperfect control of reagent incubation, multiple complex steps, and
inconsistent false positive results. Here, I have developed mechanisms to
economically improve thermal incubations, automate dried reagent flow for
multistep assays, and specifically detect pathogenic antigens while improving
final output sensitivity on paper-based devices. First, I characterize
miniaturized inkjet printed joule-heaters (microheaters) that enable thermal
control for pathogen lysis and nucleic acid amplification incubation on a
low-cost paper-based device. Next, I explore 2-Dimensional Paper Networks as a
means to automate multistep visual enhancement reactions with dried reagents to
increase the sensitivity and readability of nucleic acid detection with
paper-based devices. Lastly, I aim to create a novel Reverse-Transcription
Recombinase Polymerase Reaction mechanism to amplify and detect a specific
region of the Spike protein domain of SARS-CoV-2. This will allow the rapid
detection of SARS-CoV-2 infections to aid in managing the current COVID-19 pandemic.
In the future, these tools could be integrated into a rapid diagnostic test for
SARS-CoV-2 and other pathogens, ultimately improving the accessibility and
sensitivity of rapid diagnostics on multiple fronts.</p>
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Desenvolvimento de sensores eletroquímicos e colorimétricos para aplicações em amostras de interesse forense / Development of electrochemical and colorimetric sensors for application in forensic interest samplesAraujo, William Reis de 07 June 2016 (has links)
Esta tese apresenta os estudos e esforços visando ao desenvolvimento de sensores químicos para aplicações diversas na área forense. Foram desenvolvidos métodos eletroanalíticos para detecção e quantificação de alguns compostos comumente encontrados na adulteração de amostras de drogas de abuso (procaína, fenacetina, aminopirina, paracetamol, levamisol), além da cocaína e estudos fundamentais sobre o comportamento eletroquímico desses compostos. Empregaram-se também métodos eletroquímicos para quantificação de compostos tóxicos e perigosos como explosivos (ácido pícrico) e melamina por exemplo. Os trabalhos utilizando sensores eletroquímicos contemplam modificações eletroquímicas das superfícies eletródicas, utilização de sensores com polímeros molecularmentes impressos (MIP) e eletrodos descartáveis em papel utilizando diferentes técnicas voltamétricas e amperométricas, eletrodo disco rotatório (EDR) e microbalança de cristal de quartzo. Além da fabricação de dispositivos analíticos descartáveis em papel empregando detecção eletroquímica utilizou-se também a detecção colorimétrica para quantificação de alguns dos principais adulterantes de amostras de apreensão de cocaína, como procaína e fenacetina, bem como análises e discriminações de compostos explosivos (peroxi e nitro compostos) nessas plataformas portáteis e de baixo custo. Os métodos foram sempre desenvolvidos visando característicos como: facilidade, praticidade, baixo custo e portabilidade para análises diretamente no local de medida com mínima infraestrutura laboratorial. Por fim, são apresentados alguns estudos realizados durante estágio de pesquisa no exterior (Universidade da Califórnia - San Diego (UCSD)) na área de Wearable Sensors, em que foram desenvolvidos métodos para análises de micronutrientes no suor (zinco) e um metabólito (ácido úrico) na saliva usando sensores aplicados diretamente no corpo humano. / This thesis shows studies and efforts to the development of chemical sensors for different applications in the forensic field. Electroanalytical methods were developed for detection and quantification of some compounds (procaine, phenacetin, aminopyrine, acetaminophen, levamisole) commonly found in the drug of abuse adulteration process and cocaine, as well as, fundamental studies about the electrochemical behavior of these compounds. It was also employed electrochemical methods for quantification of hazardous compounds such as explosives (picric acid) and melamine. Analytical methods with electrochemical sensors included electrochemical modification of electrodic surfaces, molecularly imprinted polymers (MIP), and paper disposable electrochemical devices using different voltammetric and amperometric techniques, rotating disc electrode (RDE) and quartz crystal microbalance. In addition to the fabrication of paper disposable analytical devices with electrochemical detection, it was also used the colorimetric detection to quantify some of the major adulterants in cocaine seizure samples, such as procaine and phenacetin, as well as analysis and discrimination of explosive compounds (peroxy and nitro explosives) in these low cost portable platforms. All proposed methods were always developed aming at theses characteristics: ease, convenience, low cost and portability for analysis directly at the measurement site with minimal laboratory infrastructure. Finally, we presented some studies conducted during research internship abroad (University of California - San Diego (UCSD)) in the area of Wearable Sensors, which have been developed methods for micronutrient analysis in sweat (Zn) and a metabolite (Uric Acid) in saliva using sensors applied directly to the human body
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Desenvolvimento de sensores químicos de baixo custo visando ao monitoramento da qualidade e da potabilidade de águas / Development of low-cost chemical sensors aiming at monitoring water quality and potabilitySilva, José Ricardo da 30 October 2018 (has links)
A falta de acesso à água potável ainda é um problema de saúde pública no Brasil. O desenvolvimento de novos métodos analíticos de baixo custo para o reconhecimento de amostras contaminadas é uma necessidade, pois análises laboratoriais estão fora da realidade socioeconômica da população mais vulnerável. Visando contribuir para a resolução deste problema, esta tese apresenta esforços para o desenvolvimento de métodos de baixo custo para a análise de qualidade de águas ambientais. Foi estudada a associação de ferramentas quimiométricas com sensores voltamétricos para tentar discriminar amostras de águas contaminadas com espécies eletroativas. O modelo desenvolvido foi capaz de discriminar de forma satisfatória amostras contaminadas contendo chumbo(II), cobre(II), zinco(II) e nitrito. Os esforços para a redução do custo das análises também focaram no desenvolvimento de sensores com materiais de baixo custo. Um dos dispositivos voltamétricos propostos foi capaz de quantificar metais tóxicos e pesticidas, utilizando papel, grafite e cera. Foi desenvolvido também um sistema de agitação por som que resultou em um aumento significativo da sensibilidade dos dispositivos voltamétricos portáteis permitindo a quantificação de chumbo(II) até 48 nmol L-1, cádmio(II) até 370 nmol L-1 e zinco(II) até 340 nmol L-1. Outro sensor voltamétrico foi confeccionado utilizando apenas papelão como matéria prima, para o qual um laser de CO2 foi utilizado pela primeira vez com o intuito de pirolisar a superfície do papelão gerando estruturas de carbono condutoras. Sensores colorimétricos em papel foram testados com sucesso para a quantificação de fluoreto até 500 µmol L-1 em amostras de água mineral utilizando fotografias retiradas por um telefone celular para a construção de modelos12 de calibração. Com outro sistema colorimétrico em papel foi possível medir o pH de amostras utilizando um método de calibração multivariada. Como mostrado neste trabalho, o desenvolvimento e a integração dos dispositivos analíticos em papel é uma alternativa abrangente, confiável e de baixo custo para a análise da qualidade de águas ambientais. / The lack of access to safe water remains as a public health problem in Brazil. The development of new analytical methods for low cost contaminated samples recognition is necessary since the complete laboratorial procedures are away from the reality of the most socioeconomic vulnerable population. In order to contribute to solve this problem, this thesis shows our efforts to develop new low-cost analytical methods to evaluate environmental waters quality. The combination of chemometric tools with voltammetric sensors was studied to discriminate contaminated water samples with electroactive species. The proposed model was able to discriminate potable and contaminated samples containing lead(II), copper(II), zinc(II) and nitrite species. Efforts to reduce the analysis cost have also focused on the development of sensors using low-cost materials. A proposed voltammetric device fabricated with paper, graphite and wax was able to quantify heavy metals and pesticides. The use of a sound agitation system for the portable voltammetric devices resulted in a significant increase in the sensitivity allowing the quantification of lead(II) above 48 nmol L-1, cadmium(II) above 370 nmol L-1 e and zinc(II) above 340 nmol L-1 . Another voltammetric sensor was made for the first time using only cardboard as material and a CO2 laser to pyrolyze the cardboard surface generating conductive carbon structures. Paper colorimetric sensors were successfully tested for fluoride quantification in spring water samples based on photographs taken by a smartphone with a LOQ of 500 µmol L-1. Another paper colorimetric system was capable to measure the pH of samples using a multivariate calibration method. As shown in this thesis, the development and integration of analytical paper-based devices is a reliable and low-cost alternative for water quality analysis
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Desenvolvimento de sensores químicos de baixo custo visando ao monitoramento da qualidade e da potabilidade de águas / Development of low-cost chemical sensors aiming at monitoring water quality and potabilityJosé Ricardo da Silva 30 October 2018 (has links)
A falta de acesso à água potável ainda é um problema de saúde pública no Brasil. O desenvolvimento de novos métodos analíticos de baixo custo para o reconhecimento de amostras contaminadas é uma necessidade, pois análises laboratoriais estão fora da realidade socioeconômica da população mais vulnerável. Visando contribuir para a resolução deste problema, esta tese apresenta esforços para o desenvolvimento de métodos de baixo custo para a análise de qualidade de águas ambientais. Foi estudada a associação de ferramentas quimiométricas com sensores voltamétricos para tentar discriminar amostras de águas contaminadas com espécies eletroativas. O modelo desenvolvido foi capaz de discriminar de forma satisfatória amostras contaminadas contendo chumbo(II), cobre(II), zinco(II) e nitrito. Os esforços para a redução do custo das análises também focaram no desenvolvimento de sensores com materiais de baixo custo. Um dos dispositivos voltamétricos propostos foi capaz de quantificar metais tóxicos e pesticidas, utilizando papel, grafite e cera. Foi desenvolvido também um sistema de agitação por som que resultou em um aumento significativo da sensibilidade dos dispositivos voltamétricos portáteis permitindo a quantificação de chumbo(II) até 48 nmol L-1, cádmio(II) até 370 nmol L-1 e zinco(II) até 340 nmol L-1. Outro sensor voltamétrico foi confeccionado utilizando apenas papelão como matéria prima, para o qual um laser de CO2 foi utilizado pela primeira vez com o intuito de pirolisar a superfície do papelão gerando estruturas de carbono condutoras. Sensores colorimétricos em papel foram testados com sucesso para a quantificação de fluoreto até 500 µmol L-1 em amostras de água mineral utilizando fotografias retiradas por um telefone celular para a construção de modelos12 de calibração. Com outro sistema colorimétrico em papel foi possível medir o pH de amostras utilizando um método de calibração multivariada. Como mostrado neste trabalho, o desenvolvimento e a integração dos dispositivos analíticos em papel é uma alternativa abrangente, confiável e de baixo custo para a análise da qualidade de águas ambientais. / The lack of access to safe water remains as a public health problem in Brazil. The development of new analytical methods for low cost contaminated samples recognition is necessary since the complete laboratorial procedures are away from the reality of the most socioeconomic vulnerable population. In order to contribute to solve this problem, this thesis shows our efforts to develop new low-cost analytical methods to evaluate environmental waters quality. The combination of chemometric tools with voltammetric sensors was studied to discriminate contaminated water samples with electroactive species. The proposed model was able to discriminate potable and contaminated samples containing lead(II), copper(II), zinc(II) and nitrite species. Efforts to reduce the analysis cost have also focused on the development of sensors using low-cost materials. A proposed voltammetric device fabricated with paper, graphite and wax was able to quantify heavy metals and pesticides. The use of a sound agitation system for the portable voltammetric devices resulted in a significant increase in the sensitivity allowing the quantification of lead(II) above 48 nmol L-1, cadmium(II) above 370 nmol L-1 e and zinc(II) above 340 nmol L-1 . Another voltammetric sensor was made for the first time using only cardboard as material and a CO2 laser to pyrolyze the cardboard surface generating conductive carbon structures. Paper colorimetric sensors were successfully tested for fluoride quantification in spring water samples based on photographs taken by a smartphone with a LOQ of 500 µmol L-1. Another paper colorimetric system was capable to measure the pH of samples using a multivariate calibration method. As shown in this thesis, the development and integration of analytical paper-based devices is a reliable and low-cost alternative for water quality analysis
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Desenvolvimento de sensores eletroquímicos e colorimétricos para aplicações em amostras de interesse forense / Development of electrochemical and colorimetric sensors for application in forensic interest samplesWilliam Reis de Araujo 07 June 2016 (has links)
Esta tese apresenta os estudos e esforços visando ao desenvolvimento de sensores químicos para aplicações diversas na área forense. Foram desenvolvidos métodos eletroanalíticos para detecção e quantificação de alguns compostos comumente encontrados na adulteração de amostras de drogas de abuso (procaína, fenacetina, aminopirina, paracetamol, levamisol), além da cocaína e estudos fundamentais sobre o comportamento eletroquímico desses compostos. Empregaram-se também métodos eletroquímicos para quantificação de compostos tóxicos e perigosos como explosivos (ácido pícrico) e melamina por exemplo. Os trabalhos utilizando sensores eletroquímicos contemplam modificações eletroquímicas das superfícies eletródicas, utilização de sensores com polímeros molecularmentes impressos (MIP) e eletrodos descartáveis em papel utilizando diferentes técnicas voltamétricas e amperométricas, eletrodo disco rotatório (EDR) e microbalança de cristal de quartzo. Além da fabricação de dispositivos analíticos descartáveis em papel empregando detecção eletroquímica utilizou-se também a detecção colorimétrica para quantificação de alguns dos principais adulterantes de amostras de apreensão de cocaína, como procaína e fenacetina, bem como análises e discriminações de compostos explosivos (peroxi e nitro compostos) nessas plataformas portáteis e de baixo custo. Os métodos foram sempre desenvolvidos visando característicos como: facilidade, praticidade, baixo custo e portabilidade para análises diretamente no local de medida com mínima infraestrutura laboratorial. Por fim, são apresentados alguns estudos realizados durante estágio de pesquisa no exterior (Universidade da Califórnia - San Diego (UCSD)) na área de Wearable Sensors, em que foram desenvolvidos métodos para análises de micronutrientes no suor (zinco) e um metabólito (ácido úrico) na saliva usando sensores aplicados diretamente no corpo humano. / This thesis shows studies and efforts to the development of chemical sensors for different applications in the forensic field. Electroanalytical methods were developed for detection and quantification of some compounds (procaine, phenacetin, aminopyrine, acetaminophen, levamisole) commonly found in the drug of abuse adulteration process and cocaine, as well as, fundamental studies about the electrochemical behavior of these compounds. It was also employed electrochemical methods for quantification of hazardous compounds such as explosives (picric acid) and melamine. Analytical methods with electrochemical sensors included electrochemical modification of electrodic surfaces, molecularly imprinted polymers (MIP), and paper disposable electrochemical devices using different voltammetric and amperometric techniques, rotating disc electrode (RDE) and quartz crystal microbalance. In addition to the fabrication of paper disposable analytical devices with electrochemical detection, it was also used the colorimetric detection to quantify some of the major adulterants in cocaine seizure samples, such as procaine and phenacetin, as well as analysis and discrimination of explosive compounds (peroxy and nitro explosives) in these low cost portable platforms. All proposed methods were always developed aming at theses characteristics: ease, convenience, low cost and portability for analysis directly at the measurement site with minimal laboratory infrastructure. Finally, we presented some studies conducted during research internship abroad (University of California - San Diego (UCSD)) in the area of Wearable Sensors, which have been developed methods for micronutrient analysis in sweat (Zn) and a metabolite (Uric Acid) in saliva using sensors applied directly to the human body
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Miniaturized devices for bioanalysis : case of nitric oxide stored as S-nitrosothiols in biological fluids / Dispositifs miniaturisés pour l'analyse de biomolécules : cas du monoxyde d'azote stocké sous forme de s-nitrosothiols dans les fluides biologiquesIsmail, Abdul Ghani 17 October 2016 (has links)
Les S-nitrosothiols (RSNOs) sont considérés comme des stocks circulant de monoxyde d'azote (NO) et qui ont de nombreux rôles in vivo. Une variation de la proportion des taux de RSNOs a été démontrée dans de nombreuses maladies. Il est donc important de pouvoir identifier et quantifier chaque RSNO dans les fluides biologiques pour la réalisation de diagnostics médicaux. Il devient alors intéressant de développer des outils analytiques pour la détermination des RSNOs, en utilisant de faibles volumes d'échantillons biologiques. Ce travail de thèse a ainsi été orienté vers le développement d'outils analytiques miniaturisés pour l'analyse des RSNOs dans les fluides biologiques, en se focalisant sur la conception de micro-dispositifs (laboratoires sur puce), intégrant toutes les étapes de l'analyse, à savoir l'injection, la séparation, la décomposition et la détection sur un seul et même dispositif pour l'identification et la quantification des RSNOs. Pour cela, chaque étape a dû être optimisée. Ainsi, une meilleure compréhension de la réactivité des RSNOs, en terme de voies de décomposition et de cinétique, a été étudiée en développant deux méthodologies basées sur l'électrophorèse capillaire (CE) couplée soit à la spectrométrie de masse (MS) soit à une détection par mesure de conductivité sans contact à couplage capacitif (C4D). Par la suite, les conditions de décomposition et la détection sensible du NO libéré ont été réalisées en utilisant des microcapteurs électrochimiques à NO. Sur la base des résultats obtenus, deux stratégies originales ont été développées pour la détection de la totalité des RSNOs présents dans le plasma (i) via la décomposition des RSNOs en utilisant des nanoparticules d’or couplées à des microcapteurs NO et (ii) via la conception d’un dispositif miniaturisé de diagnostic sur papier. Finalement, grâce à l’optimisation des étapes de décomposition, de séparation et de détection, une étude préliminaire a été menée pour concevoir une micropuce d’électrophorèse intégrant la décomposition des RSNOs et une détection électrochimique afin de quantifier indépendamment différents RSNOs. / S- nitrosothiols (RSNOs) are considered as biological circulating stock of nitric oxide (NO) that have many roles in vivo. The variation of RSNOs proportion has been recognized in many diseases, so that the identification and quantitation of each RSNO in biological fluids is of prime importance. There is thus interest for the development of analytical tools for their determination, using low biological sample volumes. This PhD work was thus orientated towards the development of miniaturized analytical tools for the analysis of RSNOs in biological fluids, with a focus on microdevices (lab-on-a-chip), by integrating the injection, separation, decomposition and detection steps for the simultaneous identification and quantitation of various RSNOs. To this aim, a better understanding of RSNO reactivity, in terms of decomposition, was necessary and was assessed by developing two methodologies based on capillary electrophoresis (CE) coupled to different detection techniques: mass spectrometry (MS) and capacitively coupled contactless conductivity detection (C4D). Then, the conditions for RSNOs decomposition and further sensitive detection of released NO by miniaturized electrochemical NO-sensors were determined. Finally, two original strategies were developed for the detection of the total amount of RSNOs in plasma (i) decomposition using gold nanoparticles and (ii) conception of miniaturized paper-based point of care device. Thanks to the optimization of decomposition, separation and detection steps, preliminary work was conducted to develop a microchip electrophoresis coupled to RSNOs decomposition to quantify separately the different RSNOs.
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DEVELOPMENT OF ELECTROCHEMICAL AND COLORIMETRIC SENSING PLATFORMS FOR AGRICULTURE AND HEALTHCARE APPLICATIONSAna Maria NA Ulloa Gomez (14209715) 04 December 2022 (has links)
<p>Fully portable, rapid, and user-friendly sensors can successfully lead to the continuous monitoring of toxins present in the ecosystem as well as the detection of biomarkers to prevent diseases. Towards this goal, we explore electrochemical and colorimetric methods to develop platforms for the on-site detection of pesticides, heavy metals, and inflammation biomarkers. </p>
<p>This thesis presents work with the primary aim of developing non-biological and biological-based platforms. Chapter 2 describes a fully roll-to-roll electrochemical sensor with high sensing and manufacturing reproducibility for detecting nitroaromatic organophosphorus pesticides (NOPPs). This sensor is based on a flexible, screen-printed silver electrode modified with a graphene nanoplatelets coating and a zirconia coating. This chapter outlines the evaluation of the electrocatalytic activity of zirconia towards the reduction of NOPPs, using methyl parathion as a pesticide sample. Furthermore, it describes the fundamentals of electrochemistry focused on voltammetry techniques used for surface characterization and quantification. The topics reviewed serve as the first step to further manufacturing sensors through large-scale methods (e.g., roll-to-roll). Chapter 3 describes the development of a dual-modality sensing system for the detection of mercury in river waters with high accuracy and precision. The objective of this project was to incorporate colorimetric platforms into the electrochemical methods to create a dual detection design and avert false positives and negatives. Here, novel bio-functional aptamers were incorporated in a sensor containing a paper test that detects mercury by a color change and an electrochemical test that measures charge transfer resistance changes upon aptamer-target interaction. For this platform, the colorimetric test demonstrates the utilization of two systems that consist of silver and gold citrate-capped nanoparticles bio-functionalized with highly specific aptamers. The mechanism of detection of these two systems is through Ps-AgNPs and Ps-AuNPs aggregation as a result of ssDNA-Hg2+ interaction. Using Ps-AuNPs microparticles, Chapter 4 describes a fully colorimetric and smartphone-based biosensor for detecting cardiac troponin T, a biomarker for diagnosing acute myocardial infarction. Here, a comparison in detection performance between Whatman grade 1 and high-flow filter paper is reviewed. Finally, Chapter 5 evaluates the colorimetric detection performance of Ps-AuNPs microparticles towards imidacloprid and carbendazim, two of the pesticides most found in imported produce in the United States. The chapter compares gold-based microparticles in which different aptamers were immobilized, and image acquisition approaches.</p>
<p>All sensors reported in this thesis are especially suitable for environmental contaminants monitoring or point-of-care diagnosis applications. The materials selection, use or synthesis, and platforms’ performance optimization, development, and feasibility for scale-up manufacturing are expected to advance on-site biosensing technologies and their commercialization.</p>
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Advanced Applications of Raman Spectroscopy for Environmental AnalysesLahr, Rebecca Halvorson 09 January 2014 (has links)
Due to an ever-increasing global population and limited resource availability, there is a constant need for detection of both natural and anthropogenic hazards in water, air, food, and material goods. Traditionally a different instrument would be used to detect each class of contaminant, often after a concentration or separation protocol to extract the analyte from its matrix. Raman spectroscopy is unique in its ability to detect organic or inorganic, airborne or waterborne, and embedded or adsorbed analytes within environmental systems. This ability comes from the inherent abilities of the Raman spectrometer combined with concentration, separation, and signal enhancement provided by drop coating deposition Raman (DCDR) and surface-enhanced Raman spectroscopy (SERS).
Herein the capacity of DCDR to differentiate between cyanotoxin variants in aqueous solutions was demonstrated using principal component analysis (PCA) to statistically demonstrate spectral differentiation. A set of rules was outlined based on Raman peak ratios to allow an inexperienced user to determine the toxin variant identity from its Raman spectrum. DCDR was also employed for microcystin-LR (MC-LR) detection in environmental waters at environmentally relevant concentrations, after pre-concentration with solid-phase extraction (SPE). In a cellulose matrix, SERS and normal Raman spectral imaging revealed nanoparticle transport and deposition patterns, illustrating that nanoparticle surface coating dictated the observed transport properties. Both SERS spectral imaging and insight into analyte transport in wax-printed paper microfluidic channels will ultimately be useful for microfluidic paper-based analytical device (𝜇PAD) development. Within algal cells, SERS produced 3D cellular images in the presence of intracellularly biosynthesized gold nanoparticles (AuNP), documenting in detail the molecular vibrations of biomolecules at the AuNP surfaces. Molecules involved in nanoparticle biosynthesis were identified at AuNP surfaces within algal cells, thus aiding in mechanism elucidation.
The capabilities of Raman spectroscopy are endless, especially in light of SERS tag design, coordinating detection of analytes that do not inherently produce strong Raman vibrations. The increase in portable Raman spectrometer availability will only facilitate cheaper, more frequent application of Raman spectrometry both in the field and the lab. The tremendous detection power of the Raman spectrometer cannot be ignored. / Ph. D.
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SCALABLE MANUFACTURING OF PRINTED APTASENSORS: DETECTION OF FOODBORNE PATHOGENS AND ENVIRONMENTAL CONTAMINANTSLixby Susana Diaz (8464110) 21 June 2022 (has links)
<p>The development of low-cost, and reliable platforms for on-site detection of pathogenic agents, and toxic environmental traces is still a critical need for real-time monitoring of potential environmental pollution and imminent outbreaks. The biosensors market is projected to attain 31.5 billion by 2024. In this landscape, colorimetric and electrochemical devices continue to have significant relevance, with paper-based platforms leading the point-of-care (POC) segment for pathogen detection and environmental monitoring.</p>
<p>Despite the true potential of biosensors in general, they have witnessed a slow rate in commercialization, mainly due to cost restrictions, and concerns related to their reliability and repeatability once scaled-up. This research evaluates the implementation of printing techniques as a strong approach for the fabrication of paper-based and flexible electrochemical biosensors. The results obtained demonstrated the ability to control and predict the variables affecting the sensing performance, achieving high precision of the printing parameters, and allowing optimization, and iterations since very early stages of prototype development.</p>
<p>Besides the novel fabrication approach, this work introduces the use of truncated aptameric DNA sequences for whole cell detection of E. coli O157:H7 and heavy metals (Hg2+ and As3+), providing evidence of high stability and robustness under harsh conditions. Results obtained demonstrate their equal or even superior performance when compared to antibodies.</p>
<p>We established the use of aptamer-functionalized multilayered label particles (PEI-grafted gold decorated polystyrene) with high stability as label particles. These particles address the well known drawback of non-selective aggregation typical of traditional naked Gold nanoparticles. The outstanding stability of these multilayered labels was demonstrated when used in an enhanced version of the lateral flow assay for detection of E. coli O157:H7 (state of the art for paper-based colorimetric detection of whole cell bacteria), and in a multiplexed paper-based microfluidic device for dual detection of Mercury and Arsenic. This work sets the foundation of the development of a next generation of health care and environmental monitoring devices that are portable, sensitive, quantitative, and can reliably detect multiple targets with one single test.</p>
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