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21	Design, Fabrication, and Optimization of Miniaturized Devices for Bioanalytical Applications Kumar, Suresh 01 August 2015 (has links) My dissertation work integrates the techniques of microfabrication, micro/nanofluidics, and bioanalytical chemistry to develop miniaturized devices for healthcare applications. Semiconductor processing techniques including photolithography, physical and chemical vapor deposition, and wet etching are used to build these devices in silicon and polymeric materials. On-chip micro-/nanochannels, pumps, and valves are used to manipulate the flow of fluid in these devices. Analytical techniques such as size-based filtration, solid-phase extraction (SPE), sample enrichment, on-chip labeling, microchip electrophoresis (µCE), and laser induced fluorescence (LIF) are utilized to analyze biomolecules. Such miniaturized devices offer the advantages of rapid analysis, low cost, and lab-on-a-chip scale integration that can potentially be used for point-of-care applications.The first project involves construction of sieving devices on a silicon substrate, which can separate sub-100-nm biostructures based on their size. Devices consist of an array of 200 parallel nanochannels with a height step in each channel, an injection reservoir, and a waste reservoir. Height steps are used to sieve the protein mixture based on size as the protein solution flows through channels via capillary action. Proteins smaller than the height step reach the end of the channels while larger proteins stop at the height step, resulting in separation. A process is optimized to fabricate 10-100 nm tall channels with improved reliability and shorter fabrication time. Furthermore, a protocol is developed to reduce the electrostatic interaction between proteins and channel walls, which allows the study of size-selective trapping of five proteins in this system. The effects of protein size and concentration on protein trapping behavior are evaluated. A model is also developed to predict the trapping behavior of different size proteins in these devices. Additionally, the influence of buffer ionic strength, which can change the effective cross-sectional area of nanochannels and trapping of proteins at height steps, is explored in nanochannels. The ionic strength inversely correlates with electric double layer thickness. Overall, this work lays a foundation for developing nanofluidic-based sieving systems with potential applications in lipoprotein fractionation, protein aggregate studies in biopharmaceuticals, and protein preconcentration. The second project focuses on designing and developing a microfluidic-based platform for preterm birth (PTB) diagnosis. PTB is a pregnancy complication that involves delivery before 37 weeks of gestation, and causes many newborn deaths and illnesses worldwide. Several serum PTB biomarkers have recently been identified, including three peptides and six proteins. To provide rapid analysis of these PTB biomarkers, an integrated SPE and µCE device is assembled that provides sample enrichment, on-chip labeling, and separation. The integrated device is a multi-layer structure consisting of polydimethylsiloxane valves with a peristaltic pump, and a porous polymer monolith in a thermoplastic layer. The valves and pump are fabricated using soft lithography to enable pressure-based sample actuation, as an alternative to electrokinetic operation. Porous monolithic columns are synthesized in the SPE unit using UV photopolymerization of a mixture consisting of monomer, cross-linker, photoinitiator, and various porogens. The hydrophobic surface and porous structure of the monolith allow both protein retention and easy flow. I have optimized the conditions for ferritin retention, on-chip labelling, elution, and µCE in a pressure-actuated device. Overall functionality of the integrated device in terms of pressure-controlled flow, protein retention/elution, and on-chip labelling and separation is demonstrated using a PTB biomarker (ferritin). Moreover, I have developed a µCE protocol to separate four PTB biomarkers, including three peptides and one protein. In the future, an immunoaffinity extraction unit will be integrated with SPE and µCE to enable rapid, on-chip analysis of PTB biomarkers. This integrated system can be used to analyze other disease biomarkers as well. nanofluidics microfluidics thin-film microfabrication biomarkers solid-phase extraction on-chip labeling microchip electrophoresis Chemistry
22	Investigation Of Occurrence And Fate Of Biocides In Wastewater Treatment Plants And Surface Waters Yavuz, Merve 01 February 2013 (has links) (PDF) Biocides are widely used as a preservative or as an antiseptic agent in consumer care products such as toothpaste, mouthwash, and soaps, as well as in household cleaners and even in textiles due to their high antimicrobial effectiveness. The usage of this compounds results in discharge to wastewater treatment plants and so into surface waters. Their existence in the environment is of importance due to their negative effects on aquatic environment microorganisms and human health in terms of occurrence in surface waters and their fate in wastewater treatment plants. In this scope, this study focuses on occurrence and fate of selected biocides, namely triclosan (TCS) and chlorhexidine (CHD), in wastewater treatment plants and in surface waters. It was aimed to determine the biocides levels in surface water and wastewater in Turkey. For the wastewater treatment plant (WWTP) studies, several WWTPs with different process configurations, namely, Tatlar WWTP, METU WWTP, Kayseri WWTP and Antalya WWTPs were selected. Composite wastewater samples were taken from various points along the WWTPs on a seasonally basis for one year period. For the surface water part, samples were taken monthly from three different sources with different pollution levels, namely, Kesikk&ouml / pr&uuml / Reservoir, &Ccedil / amlidere Reservoir and Eymir Lake for one year period. All water samples were analyzed for their biocide level using liquid chromatography, following solid phase cartridge extraction. As a result of analyses, TCS concentration in surface water samples was detected as in the range of 0.65-11.15 ng/L, 0.86-48.96 ng/L and 0.86-757.7 ng/L for clean, moderately polluted and polluted water sources respectively. The recovery of solid phase extraction analyses for TCS was achieved as %92. CHD concentration was determined as in the range of &lt / 1.33-5.31 ng/L for surface water samples and the recovery of extraction were calculated as %96 for CHD. The concentration of TCS in wastewater samples was measured as in the range of 1.77-94.47 ng/L and 1.40-15.09 ng/L for influent and effluent samples respectively. These ranges became 1.39-10.45 ng/L and &lt / 1.32-2.44 ng/L for CHD. The highest concentrations of biocides were observed in sludge samples with concentrations of 1117-3687 &mu / g/kg and 510-2742 &mu / g/kg for TCS and CHD. Biocide removal efficiency of primary and biological treatment together was reported as % 67.5&plusmn / 8.2 in January 2012 Tatlar WWTP analyses. TD Water Pollution 419-428
23	Sample preparation of 8-hydroxy-2’-deoxyguanosine with solid phase extraction methodology based on molecular imprinting polymers and conventional silica based phases Bergman, Nina January 2011 (has links) The aim of this study was to develop methods for sample preparation for 8-OHdG in blood plasma samples with different solid phase extraction techniques using HPLC with an elec- trochemical detector. The solid phase extraction cartridges used were Chromabond® C18, Oasis® MAX, and three types of SupelMIPTM cartridges for chloramphenicol, riboflavin, and nitroimidazoles. The SupelMIPTM cartridges are based on molecularly imprinted polymers- technique. The separation of 8-OHdG in samples extracted from blood plasma was carried out with a Thermo Quest Hypersil Division ODS column (250 mm × 4 mm, 3μm I.D.) and methanol:buffer (10:90, v/v) as mobile phase. Recovery and selectivity was studied for the different solid phase extraction methods. The highest recovery was obtained using the Chromabond C18 cartridge with a recovery of 92%, and CV coefficient 9.5% (n = 4). 8-OHdG could not be extracted on MIP-cartridges for chloramphenicol or riboflavin, but was retained on MIP columns for nitroimidazoles, and the highest recovery was 49%. SPE solid phase extraction MIP molecularly imprinted polymers HPLC Analytical chemistry Analytisk kemi
24	Comparison of The Solid Phase Extraction and The Liquid-Liquid Extraction Methods for Triarylmethanes and Corresponding Metabolites in Aquatic Animal Tissues Hsiang, Huang-Sung 01 September 2010 (has links) This research investigate the matrix effect, operation time, cost and solvent comsumption for triarylmethanes and corresponding metabolites in different aquaculture products by different extraction methods. Triarylmethane was determined by LC-ESI-MS/MS in positive mode. The analytical method validation were followed the regulation of 2002/657/EC. HPLC separation was conducted with the RP-18 column. The mobile phases consisted of 0.5 mM ammonium acetate buffer (pH 3.8, adjusted with acetic acid) ¡V acetonitrile (contained 0.1% formic acid) solution. The ratios of standard deviation to average residual time for all compounds are less than 0.05. The ion ratio is stable and allowed by the regulation of 2002/657/EC. The regression constant of calibration curve is in the range from 0.998 to 0.999. The CC£\ for MG, LMG, CV, LCV are 0.09 ¡Ó 0.05, 0.19 ¡Ó 0.14, 0.15 ¡Ó 0.13, 0.15 ¡Ó 0.10 £ggkg-1, respectively. The CC£] for MG, LMG, CV, LCV are 0.09 ¡Ó 0.05, 0.19 ¡Ó 0.14, 0.15 ¡Ó 0.13, 0.15 ¡Ó0.10 £ggkg-1, respectively. The results for SPE and liquid-liquid extraction are not significantly different; the liquid-liquid extraction have shorter operation time, cheaper cost and less solvent consumption in comparison with SPE. malachite green crystal violet triarylmethanes Liquid-Liquid Extraction Solid Phase Extraction
25	Determination of alkylphenol polyethoxylates in environmental water by liquid chromatography-tandem mass spectrometry Lan, Yi-wen 19 August 2011 (has links) A LC-MS/MS method for the analysis of alkylphenol polyethoxylates in environmental waters was developed in this study. Preatment procedures including liquid-liquid extraction and solid phase extraction were compared, it¡¦s concluded that solid phase extraction is the more suitable way due to higher recovery and better stability for the analytical results. The recovery of nonylphenol polyethoxylate and octylphenol polyethoxylate were 62.3-110.7 % and 64.9-112.0 %, limit of detection were 17.60-174.9 ng/L and 7.40-53.56 ng/L. Enviromental water samples were collected from eight sampling sites along Love River in Kaohsiung City to investigate the contents of alkylphenol polyethoxylates. The highest concentration of total alkylphenol polyethoxylates was observed at Ming-Cheng Bridge which located at the upstream of Love River. For all of the analyzed compounds, the concentration of octylphenol tetraethoxylate (40.46 £gg/L) was the highest in all of the sampling sites. It¡¦s also noticed the concentration of octylphenol polyethoxylate (20.11 £gg/L) was higher than that of nonylphenol polyehtoxylate (128.04 £gg/L). Nonylphenol polyethoxylate Alkylphenol polyethoxylate Love River Solid phase extraction LC-MS/MS Octylphenol polyethoxylate
26	Investigation of alkylphenol polyethoxylates in the aquatic environment of Hengchun peninsula Chao, Ching-hung 07 September 2012 (has links) In April and June 2012, environmental water samples were collected from fourteen sampling sites in Hengchun peninsula to investigate the contents of alkylphenol polyethoxylates. A solid phase extraction combined with LC-MS/MS method for the analysis of alkylphenol polyethoxylates in environmental waters was developed in this study. The mobile phase used methanol gradient elution with deionized water. The recovery of nonylphenol polyethoxylate and octylphenol polyethoxylate were 68~94 % and 65~93 %, limit of detection were 1.89~54.20 ng/L and 0.44~39.31 ng/L, limit of quantitative were 6.29~181 ng/L and 1.48~131 ng/L. The SsuChung river contents of NPEO and OPEO were 15.64~36.29 £gg/L and 3.14~7.37 £gg/L. The Paoli river contents of NPEO and OPEO were 16.65~76.41 £gg/L and 5.66~18.80 £gg/L. The Hou Bay contents of NPEO and OPEO were 34.79~66.72 £gg/L and 7.77~19.03 £gg/L. The Shihniou river contents of NPEO and OPEO were 26.67 £gg/L and 6.68 £gg/L. The Wanli Tong, Baisha, Houbi Lake, South Bay, Caesar and Siangjiao Bay contents of NPEO and OPEO were 14.17~48.82 £gg/L and 3.88~14.79 £gg/L. The dry season concentration contents of alkylphenol polyethoxylates were high than the wet season. The concentration of nonylphenol polyethoxylate was higher than that of octylphenol polyehtoxylate. Alkylphenol polyethoxylates Nonylphenol polyethoxylate Octylphenol polyethoxylate Solid phase extraction LC-MS/MS Hengchun peninsula
27	Isoelectric Focusing Electrophoresis Coupled with Multidimensional HPLC/MS to Analyze Trace Amount of Proteins in Human Serum. Wen, Hui 01 August 2005 (has links) none £g-HPLC serum ion exchange solid phase extraction isoelecteic point isolelecteic focusing
28	Pesticide Pollution In Surface And Ground Water Of An Agricultural Area, Kumluca, Turkey Oztas, Nur Banu 01 September 2007 (has links) (PDF) Concentrations of 17 organochlorine and 14 organophosphorus pesticides were measured in 27 ground and 11 surface water samples collected from a heavily agricultural area, Kumluca, in spring and fall seasons of 2005. The samples were preconcentrated by Solid Phase Extraction. GC-ECD and GC-NPD systems were used for quantitative determination of organochlorine and organophosphorus pesticides respectively. The quality check/quality assurance tests were performed by the analysis of field and laboratory blanks, standard reference materials, spiked control and sample matrices, surrogate standards, sampling and analysis replicates. It is observed that, sample matrix lowers average percent recoveries from 89% to 76%. The uncertainties of measurements were calculated to determine major factors affecting the analysis results. It was observed that uncertainty arising from extraction procedure was generally the highest. The most commonly observed pesticide was endosulfan (70%) and chlorpyriphos (53%) for organophosphorus and organochlorine pesticides. The highest average concentration was observed for heptachlor (26 ng/L) and fenamiphos (184 ng/L). Generally pesticides were detected more often in surface waters, where the concentrations were also higher. The concentrations of organophosphorus pesticides in spring, and organochlorine pesticides in fall season were higher. The high occurrences and detection of degradation products of chlorinated pesticides clearly indicate their intense use before 1980s. It is shown that, in Kumluca environment, degradation of these pesticides mostly occurs in surface waters. It is observed that agricultural activities affect water quality in the region. The total concentration limit (500ng/L) was exceeded for 27% of surface and 14% of ground water samples, at least once in both seasons. The legal limit for a single pesticide (100ng/L) was exceeded by 32 % of surface, 24 % of ground water samples. QD Analytical Chemistry 71-142
29	DEVELOPMENT OF FLUOROUS SOLID-PHASE EXTRACTION (FSPE) ON A MICROCHIP AND ITS APPLICATION TO PROTEOMICS XU, ZHENPO 20 November 2013 (has links) The origin of fluorous interaction was explored and experimentally examined based on both HPLC and CEC data in this project. It was found that the selective fluorous interaction is a kind of reduced instantaneous or induced dipole interaction compared to the hydrophobic interaction. A series of FPPM preparation parameters were optimized. The optimized FPPM column can resolve the components in a manner that was otherwise not possible with its non-fluorous (hydrocarbon) counterpart. Following, the CEC separation of fluorous analytes on FPPM stationary phase based upon fluorous-fluorous interaction was realized for the first time. It was also found that, quantitatively, hydrophobic stationary phases have better methylene selectivity (〖 α〗_(-CH_2-)), while fluorous stationary phases have better perfluoromethylene selectivity (〖 α〗_(-CF_2-)). Thermodynamically, ∆G_(-CF_2- → -CF_2-)^° : ∆G_(-CH_2- → -CH_2-)^° (Gibbs free energy change of transferring a –CF2– unit to pure fluorous stationary phase versus Gibbs free energy change of transferring a –CH2– unit to pure hydrophobic stationary phase) is approximately equal to 8:1. A new concept, hypothetical water percentage (HWP) based on the comparison of 〖 α〗_(-CH_2-) and〖 α〗_(-CF_2-) was proposed for the first time to quantitatively evaluate the hydrophobicity/fluorophilicity of a stationary phase. A stationary phase can be classified as fluorous stationary phase when the HWP is less than 0 (more negative indicates more fluorous), or as a hydrophobic stationary phase when the HWP is larger than 100. For the range between 0 and 100, the stationary phase can be treated as either fluorous or hydrophobic due to the similar values of〖 α〗_(-CH_2-) and〖 α〗_(-CF_2-). Fluorous tagged peptides and proteins (up to 5800 Da) were effectively separated from their non-fluorous counterparts on the FPPM stationary phase in capillary-based columns and detected both on-line with ESI-MS and off-line with MALDI-MS. Finally, the FPPM solid-phase extraction (SPE) stationary phase was transplanted from the capillary to a microchip format. This microchip exhibits the merits of both selective fluorous interaction and micro total analysis system (µTAS). / Thesis (Ph.D, Chemistry) -- Queen's University, 2013-11-19 23:11:16.636 HPLC CEC Fluorous Solid-Phase Extraction MS Proteomics Fluorous Interaction Microchip
30	Towards more selective sorbents for extraction of drugs and biomarkers from biological fluids using molecularly imprinted polymers Moein, Mohammad Mahdi January 2014 (has links) Sample preparation has a critical role as a first step in analytical processes, especially in bioanalysis and environmental analysis. A good sample preparation technique should be robust and stable, regardless of the sample matrix. The aim of this thesis is to design and synthesize molecularly imprinted polymers that can be used in various sample preparation techniques, such as on-line MEPS, on-line SPE and on-line monolithic pre-columns used for the extraction of drugs, hormones, and cancer biomarkers from human plasma and urine samples. Additional aim was to provide full automation, on-line coupling, short sample preparation time and high-throughput. In this thesis MIP in MEPS was used on-line with liquid chromatography-tandem mass spectrometry (LC/MS/MS) for the determination of sarcosine in human urine and plasma samples. The method was fully automated and the packed sorbent could be used for about hundred extractions. In additional work a coated needle with MIP-Sol-Gel as thin layer was prepared and used for the microextraction of bilirubin from human plasma and urine. Small sample volumes could be handled and the validation of the method showed that the method was robust and selective. In a further work MIP-SPE on-line with HPLC was used for the extraction and determination of dextromethorphan in human plasma samples. MIP-SPE showed a good selectivity and high recovery (87% - 92%). On-line MIP monolithic pre-column was prepared and used in a coupled system for the extraction of tramadol in human plasma and urine samples. The MIP monolithic pre-column showed good selectivity and high extraction recovery was obtained (91-96%). The extraction and analysis of human insulin in plasma and pharmaceutical formulation solutions were carried out using MIP-SPE on-line with HPLC. The validation of the method showed that the method was accurate and robust. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 5: Submitted.</p> molecularly imprinted polymer sol-gel solid phase extraction microextraction by packed sorbent monolithic column

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