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Mass spectrometry-based quantitative proteomics applied to the analysis of Saccharomyces cerevisiae heat stress response and chaperone deletion strainsJarnuczak, Andrew January 2015 (has links)
In the last decade omics technologies enabled detailed and system-wide analysis of complex biological samples. Genomics, transcriptomics and metabolomics all benefited tremendously from technological advances in their respective fields. Proteomics was revolutionised by mass spectrometry, which allowed simultaneous identification of thousands of proteins in cells, tissues and organisms. And this mainly qualitative revolution, quickly turned quantitative. This work had two main objectives. Firstly, to apply the state of the art instrumentation, data analysis and bioinformatics methods to better our understanding of basic cell biology in a model organism Saccharomyces cerevisiae. Specifically, to quantitatively describe the effects of perturbations, such as adverse environmental conditions or chaperone gene deletions, on protein abundances in the cell. Additionally, it was aimed to demonstrate and evaluate the ability of a new timeof-flight mass spectrometer to perform large-scale absolute quantification. First, it was found that yeast cells are remarkably robust to deletions of major chaperone hub proteins (Ssa1p or Ssb1p deletions). This ability was attributed to network structure and redistribution of folding workload among other related chaperones rather than simple functional redundancy. Second, to build on the first set of results, a detailed time resolved description of yeast proteome dynamics in response to heat stress was provided for the wild type and Ssb1p chaperone mutant strains. In this study, for the first time in the literature, temporal expression patterns of many hallmark heat shock proteins were elucidated. Globally, a slow and sustained proteome remodelling or 'buffering' was revealed in both strains. However, it was also shown that the cells knocked out for the Ssb1p chaperone respond to heat in a distinctly different manner to the wild type strain. Finally, consistent and reproducible absolute quantification of multiple yeast proteomes was demonstrated using a new commercial time-of-flight mass spectrometer with ion mobility separation capabilities. The data obtained revealed global differences in cellular protein content between various chaperone prefoldin mutants as well as differential expression of a set of proteins promising to be interesting targets for further investigations.
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Interferometric imaging for high sensitivity multiplexed molecular measurementsMarn, Allison M. 25 September 2021 (has links)
The diagnostic and pharmaceutical industries rely on tools for characterizing, discovering, and developing bio-molecular interactions. Diagnostic assays require high affinity capture probes and binding specificity for accurate detection of biomarkers. Selection of drug candidates depends on the drug residency time and duration of drug action. Further, biologic drugs can induce anti-drug antibodies, which require characterization to determine the impact on the drug safety and efficacy. Label-free biosensors are an attractive solution for analyzing these and other bio-molecular interactions because they provide information based on the characteristics of the molecules themselves, without disturbing the native biological systems by labeling. While label-free biosensors can analyze a broad range of analytes, small molecular weight analytes (molecular weight < 1kDa) are the most challenging. Affinity measurements for small molecular weight targets require high sensitivity and long-term signal stability. Additional difficulties occur with different liquid refractive indices that result from to temperature, composition, or matrix effects of sensor surfaces. Some solutions utitlize strong solvents to increase the solubility of small molecules, which also alter the refractive index. Moreover, diagnostics require affinity measurements in relevant solutions, of various refractive indices. When a refractive index difference exists between the analyte solution and the wash buffer, a background signal is generated, referred to as the bulk effect, obscuring the small signal due to surface binding in the presence of large fluctuations due to variations of the optical refractive index of the solutions.
The signal generated by low molecular weight analytes is small, and conventional wisdom tends toward signal amplification or resonance for detection of these small signals. With this approach, Surface Plasmon Resonance (SPR) has become the gold standard in affinity measurement technologies. SPR is an expensive and complex technology that is highly susceptible to the bulk effect. SPR uses a reference channel to correct for the bulk effect in post-processing, which requires high precision and sophisticated temperature control, further increasing the cost and complexity. Additionally, multiplexing is desirable as it allows for simultaneous measurements of multiple ligands; however, multiplexing is only possible in the imaging modality of SPR, which has lower sensitivity and difficulty with referencing. The Interferometric Reflectance Imaging Sensor (IRIS) is a low-cost, optical label-free bio-molecular interaction analysis technology capable of providing precise binding affinity measurements; however, limitations in sensitivity and usability have previously prevented its widespread adaptation. Overcoming these limitations requires the implementation of automation, compact and easy-to-use instrumentation, and increased sensitivity. Here, we explore methods for improved sensitivity and usability. We achieve noise reduction and elimination of solution artifacts (bulk effect) through engineered illumination uniformity and temporal and spatial image processing. To validate these methods, we experimentally analyze small molecule molecular interactions to demonstrate highly sensitive kinetic binding measurements, independent of solution refractive index. / 2023-09-24T00:00:00Z
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Label-Free Microfluidic Devices for Single-Cell Analysis and Liquid BiopsiesGhassemi, Parham 05 January 2023 (has links)
Mortality due to cancer is a global health issue that can be improved through further development of diagnostic and prognostic tools. Recent advancements in technologies aiding cancer research have made significant strides, however a demand for a non-invasive clinically relevant point-of-care tools exists. To accomplish this feat, the desired instrument needs to be low-cost, easy-to-operate, efficient, and have rapid processing and analysis. Microfluidic platforms in cancer research have proven to be advantageous due to its operation at the microscale, which has low costs, favorable physics, high precision, short experimentation time, and requires minimal reagent and sample sizes. Label-free technologies rely on cell biophysical characteristics to identify, evaluate, and study biological samples. Biomechanical probing of cells through deformability assays provides a label-free method of identifying cell health and monitoring response to physical and chemical stimuli. Bioimpedance analysis is an alternative versatile label-free method of evaluating cell characteristics by measuring cell response to electrical signals. Microfluidic technologies can facilitate biomechanical and bioelectrical analysis through deformability assays and impedance spectroscopy. This dissertation demonstrates scientific contributions towards single-cell analysis and liquid biopsy devices focusing on cancer research. First, cell deformability assays were improved through the introduction of multi-constriction channels, which revealed that cells have a non-linear response to deformation. Combining impedance analysis with microfluidic deformability assays provided a large dataset of mechano-electrical information, which improved cell characterization and greatly decreased post-processing times. Next, two unique biosensors demonstrated improved throughput while maintaining sensitivity of single-cell analysis assays through parallelization and incorporating machine learning for data processing. Liquid biopsies involve studying cancer cells in patient vascular systems, called circulating tumor cells (CTCs), through blood samples. CTC tests reveal valuable information on patient prognosis, diagnosis and can aide therapy selection in a minimally invasive manner. This body of work presents two liquid biopsy devices that enrich murine and human blood samples and isolate CTCs to ease detection and analysis. Additionally, a microfluidic CTC detection biosensor is introduced to reliably count and identify cancer cells in murine blood, where an extremely low-cost version of the assay is also validated. Thus, the assays presented in this dissertation show promise of microfluidic technologies towards point-of-care systems for cancer research. / Doctor of Philosophy / Cancer is the second leading cause of death worldwide with approximately 2 million new cases each year in the just United States. Significant research development for diagnostic and prognostic tools have been conducted, however they can be expensive, invasive, time-consuming, unreliable, and not always easily accessible. Thus, a tool that is cheap, minimally invasive, easy-to-use, and robust needs to be developed to combat these issues. Typical cancer studies have primarily focused on biological and biochemical methods for evaluation; however, researchers have begun to leverage small-scale biosensors that utilize biophysical attributes. Recent studies have proven that these lab-on-a-chip technologies can produce meaningful results by exploiting these biophysical characteristics. Microfluidics is a science that consists of sub-millimeter sized channels which show a great deal of promise as they require minimal materials and can quickly and efficiently analyze biological samples. Label-free methods of studying cells rely on their physical properties, such as size, deformability, density, and electrical properties. These biophysical characteristics can be easily obtained at the single-cell level through microfluidic-based assays. Measuring and monitoring these attributes can provide valuable information to help understand cancer cell response to stimuli such as chemotherapeutic drugs or other therapies. A liquid biopsy is a non-invasive method of evaluating cancer patients by studying circulating tumor cells (CTCs) that exist in their blood. This dissertation reports a wide range of label-free microfluidic assays that evaluate and study biological samples at the single-cell level and for liquid biopsies. These assays consist of microfluidic channels with sensors that can rapidly obtain biophysical characteristics and process blood samples for liquid biopsy applications. Uniquely modifying microfluidic channel geometries and sensor configurations improved upon previously developed single-cell and CTC-based tools. The resulting devices were low in cost, easy-to-use, efficient, and reliable methods that alleviates current issues in cancer research while showing clinical utility.
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Biossensores descartáveis de DNA para detecção dos vírus da zika e da dengue / Disposable DNA biosensors for zika and dengue diagnosisFaria, Henrique Antonio Mendonça 09 March 2017 (has links)
Após setenta anos de sua descoberta, o vírus da zika surgiu no Brasil, espalhou-se rapidamente pelas Américas e trouxe complicações incomuns em doenças causadas por Flavivirus, como a microcefalia. A Organização Mundial da Saúde classifica a zika como a doença viral mais preocupante da atualidade e considera urgente desenvolver novos métodos de diagnóstico para ela e doenças correlatas como a dengue. Embora existam exames para identificar infecções pelos vírus dessas duas doenças, ainda não há um método rápido, específico e de baixo custo para o diagnóstico precoce. Visando preencher essa lacuna, este trabalho teve como objetivo construir dois tipos de biossensores eletroquímicos de DNA para detecção label-free desses dois vírus. Foram fabricados eletrodos descartáveis em substrato de politereftalato de etileno metalizado com filme fino de ouro nas configurações com um e três contatos. As sequências genéticas de iniciadores e sondas de captura foram desenhadas especialmente para este trabalho com base na análise dos genomas dos vírus. O primeiro biossensor utilizou o eletrodo em uma célula eletroquímica e foi capaz de identificar sequências de DNA da zika ou da dengue. As análises por espectroscopia de impedância eletroquímica mostraram que o biossensor é seletivo à sequência alvo com limite de detecção de (9,86 ± 0,89) nmol L-1. O segundo biossensor utilizou um eletrodo de três contatos para identificação de sequências de DNA em uma gota da amostra. No contato central, usado como eletrodo de trabalho, foi imobilizada a sequência de captura e os contatos laterais funcionaram como eletrodos de referência e auxiliar. Nesse sistema as medidas de impedância indicaram limite de detecção de (25,0 ± 1,7) nmol L-1. Os biossensores desenvolvidos mostraram seletividade para identificar o material genético dos vírus da zika e da dengue nos ensaios com DNA sintético e, portanto, são promissores para a análise de amostras reais, principalmente de produtos da polimerase da cadeia reversa. / After seventy years of its discovery, zika virus has emerged in Brazil, spread rapidly throughout the Americas, bringing unusual complications in diseases caused by flaviviruses, such as microcephaly. The World Health Organization classifies zika as the most harmful viral disease today and considers urgent the development of new diagnostic methods for zika and related diseases, such as dengue. Although there are tests to identify both infections, no current diagnostic method is rapid, specific and cost-efective. This thesis describes two types of electrochemical DNA biosensors for label-free detection of these zika and dengue. Disposable electrodes were fabricated on polyethylene terephthalate substrates covered with a nanometric gold layer by thermal evaporation, manufactured in one- and three-contact configurations. Genetic sequences of primers and complementary capture probes were designed based on the analysis of the virus genomes. The first biosensor we developed used the new electrode in an electrochemical cell and was able to identify zika or dengue DNA sequences. Analyses by electrochemical impedance spectroscopy showed that these biosensors are selective for zika or dengue with a detection limit of (9.86 ± 0.89) nmol L-1. A second type of biosensor used a three-contact electrode to identify DNA sequences in a drop of sample. In the central contact, used as a working electrode, the capture sequence was immobilized and the lateral contacts acted as reference and auxiliary electrodes. In this system the impedance measurements indicated a limit of detection of (25.0 ± 1.7) nmol L-1. The developed biosensors showed selectivity for zika and dengue in the synthetic DNA assays, and therefore are promising for the analysis of real samples, especially the polymerase chain reaction amplicon.
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Biossensores descartáveis de DNA para detecção dos vírus da zika e da dengue / Disposable DNA biosensors for zika and dengue diagnosisHenrique Antonio Mendonça Faria 09 March 2017 (has links)
Após setenta anos de sua descoberta, o vírus da zika surgiu no Brasil, espalhou-se rapidamente pelas Américas e trouxe complicações incomuns em doenças causadas por Flavivirus, como a microcefalia. A Organização Mundial da Saúde classifica a zika como a doença viral mais preocupante da atualidade e considera urgente desenvolver novos métodos de diagnóstico para ela e doenças correlatas como a dengue. Embora existam exames para identificar infecções pelos vírus dessas duas doenças, ainda não há um método rápido, específico e de baixo custo para o diagnóstico precoce. Visando preencher essa lacuna, este trabalho teve como objetivo construir dois tipos de biossensores eletroquímicos de DNA para detecção label-free desses dois vírus. Foram fabricados eletrodos descartáveis em substrato de politereftalato de etileno metalizado com filme fino de ouro nas configurações com um e três contatos. As sequências genéticas de iniciadores e sondas de captura foram desenhadas especialmente para este trabalho com base na análise dos genomas dos vírus. O primeiro biossensor utilizou o eletrodo em uma célula eletroquímica e foi capaz de identificar sequências de DNA da zika ou da dengue. As análises por espectroscopia de impedância eletroquímica mostraram que o biossensor é seletivo à sequência alvo com limite de detecção de (9,86 ± 0,89) nmol L-1. O segundo biossensor utilizou um eletrodo de três contatos para identificação de sequências de DNA em uma gota da amostra. No contato central, usado como eletrodo de trabalho, foi imobilizada a sequência de captura e os contatos laterais funcionaram como eletrodos de referência e auxiliar. Nesse sistema as medidas de impedância indicaram limite de detecção de (25,0 ± 1,7) nmol L-1. Os biossensores desenvolvidos mostraram seletividade para identificar o material genético dos vírus da zika e da dengue nos ensaios com DNA sintético e, portanto, são promissores para a análise de amostras reais, principalmente de produtos da polimerase da cadeia reversa. / After seventy years of its discovery, zika virus has emerged in Brazil, spread rapidly throughout the Americas, bringing unusual complications in diseases caused by flaviviruses, such as microcephaly. The World Health Organization classifies zika as the most harmful viral disease today and considers urgent the development of new diagnostic methods for zika and related diseases, such as dengue. Although there are tests to identify both infections, no current diagnostic method is rapid, specific and cost-efective. This thesis describes two types of electrochemical DNA biosensors for label-free detection of these zika and dengue. Disposable electrodes were fabricated on polyethylene terephthalate substrates covered with a nanometric gold layer by thermal evaporation, manufactured in one- and three-contact configurations. Genetic sequences of primers and complementary capture probes were designed based on the analysis of the virus genomes. The first biosensor we developed used the new electrode in an electrochemical cell and was able to identify zika or dengue DNA sequences. Analyses by electrochemical impedance spectroscopy showed that these biosensors are selective for zika or dengue with a detection limit of (9.86 ± 0.89) nmol L-1. A second type of biosensor used a three-contact electrode to identify DNA sequences in a drop of sample. In the central contact, used as a working electrode, the capture sequence was immobilized and the lateral contacts acted as reference and auxiliary electrodes. In this system the impedance measurements indicated a limit of detection of (25.0 ± 1.7) nmol L-1. The developed biosensors showed selectivity for zika and dengue in the synthetic DNA assays, and therefore are promising for the analysis of real samples, especially the polymerase chain reaction amplicon.
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Comparative Proteomic Analysis of Cotton Fiber Development and Protein Extraction Method Comparison in Late Stage FibersMujahid, Hana, Pendarvis, Ken, Reddy, Joseph, Nallamilli, Babi, Reddy, K., Nanduri, Bindu, Peng, Zhaohua 03 February 2016 (has links)
The distinct stages of cotton fiber development and maturation serve as a single-celled model for studying the molecular mechanisms of plant cell elongation, cell wall development and cellulose biosynthesis. However, this model system of plant cell development is compromised for proteomic studies due to a lack of an efficient protein extraction method during the later stages of fiber development, because of a recalcitrant cell wall and the presence of abundant phenolic compounds. Here, we compared the quality and quantities of proteins extracted from 25 dpa (days post anthesis) fiber with multiple protein extraction methods and present a comprehensive quantitative proteomic study of fiber development from 10 dpa to 25 dpa. Comparative analysis using a label-free quantification method revealed 287 differentially-expressed proteins in the 10 dpa to 25 dpa fiber developmental period. Proteins involved in cell wall metabolism and regulation, cytoskeleton development and carbohydrate metabolism among other functional categories in four fiber developmental stages were identified. Our studies provide protocols for protein extraction from maturing fiber tissues for mass spectrometry analysis and expand knowledge of the proteomic profile of cotton fiber development.
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Advanced optical fibre grating sensors for biochemical applicationsLiu, Chen January 2019 (has links)
This thesis describes a detailed study of advanced fibre optic sensors and their applications for label-free biochemical detection. The major contributions presented in this thesis are summarised below. A self-assembly based in-situ layer-by-layer (i-LbL) or multilayer deposition technique has been developed to deposit the 2D material nanosheets on cylindrical fibre devices. This deposition technique is based on the chemical bonding associated with the physical adsorption, securing high-quality 2D materials coating on specific fibre cylindrical surface with strong adhesion as well as a prospective thickness control. Then a " Photonic-nano-bio configuration", which is bioprobes immobilised 2D-(nano)material deposited fibre grating, was built. 2D material overlay provides a remarkable analytical platform for bio-affinity binding interface due to its exceptional optical and biochemical properties. EDC (1-ethyl-3-(3-dimethylaminopropyl)carbodiimide) and NHS (NHydroxysuccinimide) were used to immobilise bioprobes. This kind of configuration is considered to have many advantages such as: enhanced RI sensitivity, enrich immobilisation sites, improved binding efficiency, selective detection. Followed by this configuration, several label-free biosensors were developed. For example, graphene oxide coated dual-peak long period grating (GO-dLPG) based immunosensor has been implemented for ultrasensitive detection of antibody/antigen interaction. The GO-LPG based biosensor has been developed for label-free haemoglobin detection. Apart from biosensors, the black phosphorus (BP) integrated tilted fibre grating (TFG) has been proposed, for the first time, as BP-fibre optic chemical sensor for heavy metal (Pb2+ ions) detection, demonstrating ultrahigh sensitivity, lower limit of detection and wider concentration range. Ultrafast laser micromachining technology has been employed to fabricate long period grating (LPG) and microstructures on optical fibre. The ultrafast laser micromachined polymer optical fibre Bragg grating (POFBG) has been developed for humidity sensing, showing the significant improvement with the reduced response time.
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Electrochemical Studies of DNA Films on Gold SurfacesShamsi, Mohtashim Hassan 07 January 2013 (has links)
DNA-metal ion interactions are critical for stabilizing conformations of double stranded (ds) DNA and through specific binding sites will influence the interaction of DNA with other molecules. It has been shown that different metal ions bind to different sites within nucleic acids. Work in this thesis exploits the interactions of Zn2+ with nucleic acids that are linked to surfaces. Zn2+ can interact with the phosphodiester backbone and engage in interactions with the purine nucleobases. Electrochemical studies of ds-DNA films have demonstrated that in the presence of Zn2+ films containing a single nucleotide mismatch give rise to a specific electrochemical signature. Electrochemical impedance spectroscopy (EIS) allows the discrimination of mismatched DNA films from those that are fully matched by monitoring differences in the resistance of charge transfer. Scanning electrochemical microscopy (SECM) allows multiplexing of the data acquisition and monitoring of the current response I, which is attenuated as a function of mismatch. In this thesis, various potential factors were explored in detail that may impact the discrimination of nucleotide mismatches in ds-DNA films by EIS and SECM. These factors include the position of the mismatch, its type, the number of mismatches, the length of the DNA duplex, and the length of target sequences. In particular, when the two strands are of unequal length, the resulting nucleotide overhang may mask the mismatch signature. Such overhangs are expected in real biosensor applications, in which the DNA is isolated from cellular targets. Results presented here clearly demonstrate that mismatches are readily distinguished from fully matched strands even in overhang systems, suggesting that this approach has promise for realistic sensor applications.
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Label-free Biodetection with Individual Plasmonic NanoparticlesNusz, Gregory January 2010 (has links)
<p>The refractive index sensitivity of plasmonic nanoparticles is utilized in the development of real-time, label-free biodetection. Analyte molecules that bind to receptor-conjugated nanoparticles cause an increase in local refractive index that in turn induces an energy shift in the optical resonance of the particle. Biomolecular binding is quantified by quantitatively measuring these resonance shifts. This work describes the application and optimization of a biomolecular detection system based on gold nanorods as an optical transducer.</p>
<p>A microspectroscopy system was developed to collect scattering spectra of single nanoparticles, and measure shifts of the spectra as a function of biomolecular binding. The measurement uncertainty of LSPR peak shifts of the system was demonstrated to be 0.3 nm. An analytical model was also developed that provides the optimal gold nanorod geometry for detection with specified receptor-analyte pair. The model was applied to the model biotin-streptavidin system, which resulted in sensing system with a detection limit of 130 pM - an improvement by four orders of magnitude over any other single-particle biodetection previously presented in the literature.</p>
<p>Alternative optical detection schemes were also investigated that could facilitate mulitplexed biosensing. A theoretical model was built to investigate the efficacy of using a multi-channel detector analogous to a conventional RGB camera. The results of the model indicated that even in the best case, the detection capabilities of such a system did not provide advantages over the microspectroscopic approach.</p>
<p>We presented a novel hyperspectral detection scheme we term Dual-Order Spectral Imaging (DOSI) which is capable of simultaneously measuring spectra of up to 160 individual regions within a microscope's field of view. This technique was applied to measuring shifts of individual nanoparticles and was found to have a peak measurement uncertainty of 1.29 nm, at a measurement rate of 2-5 Hz.</p> / Dissertation
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Electrochemical Studies of DNA Films on Gold SurfacesShamsi, Mohtashim Hassan 07 January 2013 (has links)
DNA-metal ion interactions are critical for stabilizing conformations of double stranded (ds) DNA and through specific binding sites will influence the interaction of DNA with other molecules. It has been shown that different metal ions bind to different sites within nucleic acids. Work in this thesis exploits the interactions of Zn2+ with nucleic acids that are linked to surfaces. Zn2+ can interact with the phosphodiester backbone and engage in interactions with the purine nucleobases. Electrochemical studies of ds-DNA films have demonstrated that in the presence of Zn2+ films containing a single nucleotide mismatch give rise to a specific electrochemical signature. Electrochemical impedance spectroscopy (EIS) allows the discrimination of mismatched DNA films from those that are fully matched by monitoring differences in the resistance of charge transfer. Scanning electrochemical microscopy (SECM) allows multiplexing of the data acquisition and monitoring of the current response I, which is attenuated as a function of mismatch. In this thesis, various potential factors were explored in detail that may impact the discrimination of nucleotide mismatches in ds-DNA films by EIS and SECM. These factors include the position of the mismatch, its type, the number of mismatches, the length of the DNA duplex, and the length of target sequences. In particular, when the two strands are of unequal length, the resulting nucleotide overhang may mask the mismatch signature. Such overhangs are expected in real biosensor applications, in which the DNA is isolated from cellular targets. Results presented here clearly demonstrate that mismatches are readily distinguished from fully matched strands even in overhang systems, suggesting that this approach has promise for realistic sensor applications.
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