Synthesis and Characterization of Polymeric Ionic Liquids and Applications in Solid-Phase Microextraction Coupled with Gas Chromatography

Meng, Yunjing

19 September 2011

No description available.

Analytical Chemistry

polymeric ionic liquids

solid-phase microextraction

gas chromatography

Quantitation of Halogenated Anisoles in Wine via SPME – GC/MS

Milo, John A.

January 2008

No description available.

Chemistry

solid-phase microextraction

haloanisoles

gas chromatography mass spectrometry

Study of volatile compound formation in oxidized lipids and volatile compound retention in processed orange juice

Boff, Jeffrey M.

01 October 2003

No description available.

Singlet Oxygen

Solid Phase Microextraction

Volatiles

Flavor

High Pressure Processingi

The Development of Novel Phases with Photoresist for Capillary Electrophoresis, Capillary Electrochromatography, and Solid Phase Microextraction

Steach, Jeremy Kenneth

29 July 2008

No description available.

Chemistry

coatings

chromatography

electrospinning

photoresist

solid phase microextraction

Electrospun Fibers for Solid-Phase Microextraction

Zewe, Joseph William

09 September 2010

No description available.

Analytical Chemistry

Chemistry

solid-phase microextraction

electrospinning

separation science

Evaluation of Initial Flavor Fade in Fresh Roasted Peanuts using Gas Chromatography-Flame Ionization Detection, Gas Chromatography-Olfactometry, Sensory Analysis, and Chemosensory Techniques

Powell, Jodi

17 November 2004

Preventing flavor fade requires an understanding of the relationship between carbonyl amine and lipid oxidation reactions. The polyunsaturated fatty acid content of lipids in peanuts makes them more susceptible to lipid oxidation. The major by-products of the oxidation reaction are nonanal, hexanal, octanal, and decanal. These chemicals are associated with cardboardy, painty, and oxidized flavors associated with flavor fade. The carbonyl-amine reaction yields a variety of pyrazines with positive flavor attributes. Initial flavor notes were explored through sensory work, Gas Chromatography-Olfactometry, and chemical analysis. The fresh roasted volatiles produced from roasted peanuts and the aldehydes resulting from oxidation were also evaluated using GC-FID to quantify and identify the pyrazines and hexanal over a 21 day storage period. Electronic Nose was used to determine differences between storage periods. Gas chromatography-Olfactometry identified potent pyrazines contributing to fresh roasted peanutty aroma in fresh peanuts. Using GC-FID a significant decrease (p<.05) in 2-ethylpyrazine and 2,3-diethylpyrazine concentration was found over a 21-day period. No significant difference (p>0.05) was noted in the other pyrazines evaluated. A significant increase (p<0.05) was noted in the hexanal concentration over a 21-day period. The peroxide values and sensory analysis correlated directly with the GC-FID results with a significant increase (p<0.05) in peroxide value at Day 14 and Day 21, and a significant decrease (p<0.05) in fresh roasted peanuty flavor from days 0-21 and a significant increase (p<.05) in painty, cardboardy and bitter from days 7-21. The electronic nose successfully separated Day 0 and Day 21 samples from Day 7 and 14, which were also separated, but with minimal overlap. / Ph. D.

solid phase microextraction

gas chromatography-olfactometry

roasted peanuts

Pyrazines

The Effect of Wine Matrix Ingredients on 3-Alkyl-2-methoxypyrazines Measurements by Headspace Solid-Phase Microextraction (HS-SPME)

Hartmann, Peter J.

15 April 2003

The effect of wine matrix ingredients and conditions on the headspace (HS) sampling of 3-alkyl-2-methoxypyrazines was investigated with solid-phase microextraction (SPME) and capillary gas chromatography, using a nitrogen phosphorus detector. Changes in the recovery of 3-ethyl-, isopropyl-, sec-butyl-, and isobutyl-2-methoxypyrazines from the static headspace of synthetic wine matrices spiked with 5mg/L of each analyte were investigated and reported as a function of SPME fiber type, extraction time, and temperature. The influence of pH, ethanol, phenolics, and ground oak was studied. DVB/Carboxen?/PDMS SPME fibers at an extraction temperature of 50°C for 30 minutes with 30% (w/v) added sodium chloride resulted in the highest analyte recoveries. Although, PDMS (100 micron) SPME fibers at an extraction temperature of 35°C for 30 minutes with 30% (w/v) added sodium chloride resulted in the lower analyte recoveries, the fiber remained functional after 50 to 75 analyses after other coatings deteriorated. Changing the sample ethanol concentration from 0 to 20% (v/v) resulted in an exponential decrease in the recovered analytes. Below pH 2, there was extensive loss of the analytes in the headspace. No measurable impact on alkylmethoxypyrazine headspace concentrations was observed with exposures to selected phenolics and to ground oak. / Master of Science

Alkyl-methoxypyraxines

Gas Chromatography

Headspace Solid-phase Microextraction

Wine

Development, investigation and application of new microextraction systems for determination of volatile aromatic hydrocarbons / Naujų mikroekstrakcijos sistemų kūrimas, tyrimas ir taikymas lakių aromatinių angliavandenilių nustatymui

Pusvaškienė, Edita

22 February 2011

A new solid phase microextraction system composed of nanotubes coating fixed on a stainless steel support is suggested. Thermal stability and selectivity of the system was examined. It was determined that the system can be used for direct and headspace extraction of volatile aromatic hydrocarbons. Possibilities of four liquid phase microextraction techniques – hollow fibre liquid phase microextraction, liquid phase microextraction based on the solidification of a floating drop, dispersive liquid-liquid microextraction and dispersion-solidification liquid-liquid microextraction – for the extraction of volatile aromatic hydrocarbons were investigated. Extraction conditions of the investigated methods were optimized and the main analytical characteristics were determined. For all the methods detection limits and repeatability of the results are close. An exception is dispersive liquid-liquid microextraction with slightly higher detection limits. An extraction is especially fast using dispersive liquid-liquid microextraction and dispersion-solidification liquid-liquid microextraction. The most time-consuming method is liquid phase microextraction based on the solidification of a floating drop. All the methods are suitable for clean sample extraction. For the extraction from complex matrices the most suitable methods are headspace solid phase microextraction and hollow fibre liquid phase microextraction. The prepared microextraction techniques were applied for water and snow... [to full text] / Pasiūlyta nauja kietafazės mikroekstrakcijos sistema, kurioje nerūdijančio plieno strypelis dengtas anglies nanovamzdeliais, ištirtas jos terminis stabilumas ir atrankumas, nustatyta, kad sistema tinka lakių aromatinių angliavandenilių ekstrakcijai iš tirpalo ir iš viršerdvės. Ištirtos keturių skysčių-skysčių mikroekstrakcijos metodų - skysčių-skysčių mikroekstrakcijos kapiliare, mikroekstrakcijos užšaldomu tirpiklio lašu, dispersinės skysčių-skysčių mikroekstrakcijos ir dispersinės skysčių-skysčių mikroekstrakcijos užšaldant ekstraktą - galimybės ekstrahuoti lakius aromatinius angliavandenilius. Optimizuotos tirtų metodų ekstrakcijos sąlygos, nustatytos pagrindinės analizinės charakteristikos. Visų metodų rezultatų pasikartojamumas ir aptikimo ribos artimi. Išimtis – dispersinė skysčių-skysčių mikroekstrakcija, kuria gautos kiek didesnės aptikimo ribos. Greičiausi ekstrakcijos metodai - dispersinė skysčių-skysčių mikroekstrakcija ir dispersinė skysčių-skysčių mikroekstrakcija užšaldant ekstraktą, ilgiausiai trunka mikroekstrakcija užšaldomu tirpiklio lašu. Švarių mėginių ekstrakcijai tinka visi tirti metodai, užterštiems mėginiams geriau tinka kietafazė mikroekstrakcija iš viršerdvės arba skysčių-skysčių mikroekstrakcija kapiliare. Paruoštos lakių aromatinių angliavandenilių mikroekstrakcijos metodikos pritaikytos vandens ir sniego mėginių analizei.

Chemistry

Volatile aromatic hydrocarbons

Solid phase microextraction

Liquid phase microextraction techniques

Lakūs aromatiniai angliavandeniliai

Kietafazė mikroekstrakcija

Naujų mikroekstrakcijos sistemų kūrimas, tyrimas ir taikymas lakių aromatinių angliavandenilių nustatymui / Development, investigation and application of new microextraction systems for determination of volatile aromatic hydrocarbons

Pusvaškienė, Edita

22 February 2011

Pasiūlyta nauja kietafazės mikroekstrakcijos sistema, kurioje nerūdijančio plieno strypelis dengtas anglies nanovamzdeliais, ištirtas jos terminis stabilumas ir atrankumas, nustatyta, kad sistema tinka lakių aromatinių angliavandenilių ekstrakcijai iš tirpalo ir iš viršerdvės. Ištirtos keturių skysčių-skysčių mikroekstrakcijos metodų - skysčių-skysčių mikroekstrakcijos kapiliare, mikroekstrakcijos užšaldomu tirpiklio lašu, dispersinės skysčių-skysčių mikroekstrakcijos ir dispersinės skysčių-skysčių mikroekstrakcijos užšaldant ekstraktą - galimybės ekstrahuoti lakius aromatinius angliavandenilius. Optimizuotos tirtų metodų ekstrakcijos sąlygos, nustatytos pagrindinės analizinės charakteristikos. Visų metodų rezultatų pasikartojamumas ir aptikimo ribos artimi. Išimtis – dispersinė skysčių-skysčių mikroekstrakcija, kuria gautos kiek didesnės aptikimo ribos. Greičiausi ekstrakcijos metodai - dispersinė skysčių-skysčių mikroekstrakcija ir dispersinė skysčių-skysčių mikroekstrakcija užšaldant ekstraktą, ilgiausiai trunka mikroekstrakcija užšaldomu tirpiklio lašu. Švarių mėginių ekstrakcijai tinka visi tirti metodai, užterštiems mėginiams geriau tinka kietafazė mikroekstrakcija iš viršerdvės arba skysčių-skysčių mikroekstrakcija kapiliare. Paruoštos lakių aromatinių angliavandenilių mikroekstrakcijos metodikos pritaikytos vandens ir sniego mėginių analizei. / A new solid phase microextraction system composed of nanotubes coating fixed on a stainless steel support is suggested. Thermal stability and selectivity of the system was examined. It was determined that the system can be used for direct and headspace extraction of volatile aromatic hydrocarbons. Possibilities of four liquid phase microextraction techniques – hollow fibre liquid phase microextraction, liquid phase microextraction based on the solidification of a floating drop, dispersive liquid-liquid microextraction and dispersion-solidification liquid-liquid microextraction – for the extraction of volatile aromatic hydrocarbons were investigated. Extraction conditions of the investigated methods were optimized and the main analytical characteristics were determined. For all the methods detection limits and repeatability of the results are close. An exception is dispersive liquid-liquid microextraction with slightly higher detection limits. An extraction is especially fast using dispersive liquid-liquid microextraction and dispersion-solidification liquid-liquid microextraction. The most time-consuming method is liquid phase microextraction based on the solidification of a floating drop. All the methods are suitable for clean sample extraction. For the extraction from complex matrices the most suitable methods are headspace solid phase microextraction and hollow fibre liquid phase microextraction. The prepared microextraction techniques were applied for water and snow... [to full text]

Chemistry

Lakūs aromatiniai angliavandeniliai

Kietafazė mikroekstrakcija

Volatile aromatic hydrocarbons

Solid phase microextraction

Liquid phase microextraction techniques

Strategies to Improve Solid Phase Microextraction Sensitivity: Temperature, Geometry and Sorbent Effects

Jiang, Ruifen

January 2013

Solid phase microextraction (SPME) has been widely used in a variety of sample matrices and proven to be a simple, fast and solvent-free sample preparation technique. A challenging limitation in the further development of this technique has been the insufficient sensitivity for some trace applications. This limitation lies mainly in the small volume of the extraction phase. According to the fundamentals of SPME, different strategies can be employed to achieve higher sensitivity for SPME sampling. These include cooling down the extraction phase, preparing a high capacity particle-loading extraction phase, as well as using a thin film with high surface area-to-volume ratio as the extraction phase. In this thesis, four sampling approaches were developed for high sensitivity sampling by employing cold fiber, thin film, cooling membrane and particle loading membrane as sampling tools. These proposed methods were applied to liquid, solid and particularly trace gas analysis. First, a fully automated cold fiber device that improves the sensitivity of the technique by cooling down the extraction phase was developed. This device was coupled to a GERSTEL® MultiPurpose Sampler (MPS 2), and applied to the analysis of volatiles and semi-volatiles in aqueous and solid matrices. The proposed device was thoroughly evaluated for its extraction performance, robustness, reproducibility and reliability by gas chromatograph/mass spectrometer (GC/MS). The evaluation of the automated cold fiber device was carried out using a group of compounds characterized by different volatilities and polarities. Extraction efficiency and analytical figures of merit were compared to commercial SPME fibers. In the analysis of aqueous standard samples, the automated cold fiber device showed a significant improvement in extraction efficiency when compared to commercial polydimethylsiloxane (PDMS) and non-cooled cold fiber. This was achieved due to the low temperature of the coating during sampling. Results from the cold fiber and commercial divinylbenzene/carboxen/polydimethylsiloxane (DVB/CAR/PDMS) fiber analysis of solid sample matrices were obtained and compared. Results demonstrated that the temperature gap between the sample matrix and the coating significantly improved the distribution coefficient, and consequently, the extraction amount. The newly automated cold fiber device presents a platform for headspace analysis of volatiles and semi-volatiles for a large number of samples, with improved throughput and sensitivity. Thin film microextraction (TFME) improves the sensitivity by employing a membrane with a high surface area-to-volume ratio as the extraction phase. In Chapter 3, a simple non-invasive sample preparation method using TFME is proposed for sampling volatile skin emissions. Evaluation experiments were conducted to test the reproducibility of the sampling device, the effect of the membrane size, and the method for storage. Results supported the reproducibility of multi-membrane sampling, and demonstrated that sampling efficiency can be improved using a larger membrane. However, ability to control the sampling environment and time was proved to be critical in order to obtain reliable information; the in vivo skin emission sampling was also influenced by skin metabolism and environmental conditions. Next, the method of storage was fully investigated for the membrane device before and after sampling. This investigation of storage permitted the sampling and instrument analysis to be conducted at different locations. Finally, the developed skin sampling device was applied in the identification of dietary biomarkers after garlic and alcohol ingestion. In this experiment, the previously reported potential biomarkers dimethyl sulphone, allyl methyl sulfide and allyl mercaptan were detected after garlic intake, and ethanol was detected after the ingestion of alcohol. Experiments were also conducted in the analysis of volatile organic compounds (VOCs) from upper back, forearm and back thigh of the body on the same individual. Results showed that 27 compounds can be detected from all of the 3 locations. However, these compounds were quantitatively different. In addition, sampling of the upper back, where the density of sebaceous glands is relatively high, detected more compounds than the other regions. In Chapter 4, a novel sample preparation method that combines the advantages of cold fiber and thin film was developed to achieve the high extraction efficiency necessary for high sensitivity gas sampling. A cooling sampling device was developed for the thin film microextraction. Method development for this sampling approach included evaluation of membrane temperature effect, membrane size effect, air flow rate and humidity effect. Results showed that high sensitivity for equilibrium sampling can be achieved by either cooling down the membrane and/or using a large volume extraction phase. On the other hand, for pre-equilibrium extraction, in which the extracted amount was mainly determined by membrane surface area and diffusion coefficient, high sensitivity was obtained by thin membranes with a large surface area and/or high sampling flow rate. In addition, humidity evaluations showed no significant effect on extraction efficiency due to the absorption property of the liquid extraction phase. Next, the limit of detection (LOD) and reproducibility of the developed cooling membrane gas sampling method were evaluated. LOD with a membrane radius of 1 cm at room temperature sampling were 9.24 ng/L, 0.12 ng/L, 0.10 ng/L for limonene, cinnamaldehyde and 2-pentadecanone, respectively. Intra- and inter-membrane sampling reproducibility had a relative standard deviation (RSD%) lower than 8% and 13%, respectively. Results uniformly demonstrated that the proposed cooling membrane device could serve as a powerful tool for gas in trace analysis. In Chapter 5, a particle-loading membrane was developed to combine advantages of high distribution coefficient and high surface area geometry, and applied in trace gas sampling. Bar coating, a simple and easy preparation method was applied in the preparation of the DVB/PDMS membrane. Membrane morphology, particle ratio, membrane size and extraction efficiency were fully evaluated for the prepared membrane. Results show that the DVB particles are uniformly distributed in the PDMS base. The addition of a DVB particle enhanced the stiffness of the membrane to some extent, and improved the extraction capacity of the membrane. Extraction capacity for benzene was enhanced by a factor of 100 when the membrane DVB particle ratio increased from 0% to 30%. Additionally, the prepared DVB/PDMS membrane provided higher extraction efficiency than pure PDMS membrane and DVB/PDMS fiber, especially for highly volatile and polar compounds. The high reproducibility of the prepared DVB/PDMS membrane in air sampling demonstrated the advantage of the bar coating preparation method, and also permitted quantitative analysis. Last, the prepared particle-loading membrane was applied to semi-quantitative and quantitative analysis of indoor and outdoor air, respectively. Both the equilibrium calibration method and diffusion-based calibration method were proposed for the quantitative analysis. Results showed that the high capacity particle-loading membrane can be used for monitoring trace analytes such as perfume components and air pollutants.

Solid phase microextraction (SPME)

Cold fiber

Thin film microextraction

Particle loading membrane

Cooling membrane

SPME sensitivity

Chemistry