In this paper, the preparation and performance of long, high-efficiency poly(styrene-divinylbenzene) (PS-DVB), 10-microm-i.d. porous layer open tubular (PLOT) capillary columns are described. PLOT capillaries ( approximately 3% RSD column-to-column retention time), with relatively high permeability, were prepared by in-situ polymerization. Relatively high loading capacities, approximately 100 fmol for angiotensin I and approximately 50 fmol for insulin, were obtained with a 4.2 m x 10-microm-i.d. PLOT column. Low detection levels (attomole to sub-attomole) were achieved when the column was coupled on-line with a linear ion trap MS (LTQ). Analysis of human epidermal growth factor receptor (EGFR), a large transmembrane tyrosine kinase receptor with heterogeneous phosphorylation and glycosylation structures, was obtained at the 25 fmol level. The PLOT column yielded a peak capacity of approximately 400 for the separation of a complex tryptic digest mixture when the sample preparation included a 50-microm-i.d. PS-DVB monolithic precolumn and ESI-MS detection. As an example of the power of the column, 3046 unique peptides covering 566 distinct Methanosarcina acetivorans proteins were identified from a 50 ng in-gel tryptic digest sample combining five cuts in a single LC/MS/MS analysis using the LTQ. The results demonstrate the potential of the PLOT column for high-resolution LC/MS at the ultratrace level.
Following on our recent work, on-line one dimensional (1D) and two dimensional (2D) PLOT/LC-ESI-MS platforms using 3.2 m × 10 μm i.d. poly(styrenedivinylbenzene) (PS-DVB) porous layer open tubular (PLOT) columns have been developed to provide robust, high performance and ultrasensitive proteomic analysis. Using a PicoClear tee, the dead volume connection between a 50 μm i.d. PS-DVB monolithic microSPE column and the PLOT column was minimized. The microSPE/PLOT column assembly provided a separation performance similar to that obtained with direct injection onto the PLOT column at a mobile phase flow rate of 20 nL/min. The trace analysis potential of the platform was evaluated using an in-gel tryptic digest sample of a gel fraction (15 to 40 kDa) of a cervical cancer (SiHa) cell line. As an example of the sensitivity of the system, ∼2.5 ng of protein in 2 μL solution, an amount corresponding to 20 SiHa cells, was subjected to on-line microSPE-PLOT/LC-ESIMS/MS analysis using a linear ion trap MS. 237 peptides associated with 163 unique proteins were identified from a single analysis when using stringent criteria associated with a false positive rate less than 1% . The number of identified peptides and proteins increased to 638 and 343, respectively, as the injection amount was raised to ∼45 ng of protein, an amount corresponding to 350 SiHa cells. In comparison, only 338 peptides and 231 unique proteins were identified (false positive rate again less than 1%) from 750 ng of protein from the identical gel fraction, an amount corresponding to 6000 SiHa cells, using a typical 15 cm × 75 μm i.d. packed capillary column. The greater sensitivity, higher recovery, and higher resolving power of the PLOT column resulted in the increased number of identifications from only ∼5% of the injected sample amount. The resolving power of the microSPE/PLOT assembly was further extended by 2D chromatography via combination of the high-efficiency reversed phase PLOT column with strong cation exchange chromatography (SCX). As an example, 1071 peptides associated with 536 unique proteins were identified from 75 ng of protein from the same gel fraction, an amount corresponding to 600 cells, using 5 ion exchange fractions in online 2D SCX-PLOT/LC-MS. The 2D system, implemented in an automated format, led to simple and robust operation for proteomic analysis. These promising results demonstrate the potential of the PLOT column for ultratrace analysis.Global characterization of proteins from complex mixtures over a wide dynamic concentration range is one of the challenges of current proteomic studies. the first dimension and reversed phase (RP) as the second dimension of separation is often used. 4-8 Current existing 2D approaches are typically operated with relatively large amounts of sample (low microgram); however, the study of much smaller sample amounts (e.g., limited number of cells obtained from laser capture microdissection) are difficult. 9-10 New 2D LC/ MS approaches with improved sensitivity and robust operation are thus h...
In this study a novel glass membrane was prepared for conducting high voltage (HV) to solution in the channel of a microfabricated device for generation of liquid electrospray. Taylor cone formation and mass spectra obtained from this microdevice confirmed the utility of the glass membrane, but voltage conduction through the membrane could not be successfully explained based solely on the conductivity of the glass itself. This novel method for developing a high-voltage interface for microdevices avoids direct metal/liquid contact eliminating bubble formation in the channel due to water hydrolysis on the surface of the metal. Further, this arrangement produces no dead volume as is often found with traditional liquid junctions. At the same time, preliminary investigations into the outlet design of glass microdevices for interfacing with electrospray mass spectrometry, was explored. Both the exit shape and the use of hydrophobic coatings at the channel exit of the microdevice electrospray interface were evaluated using standard proteins with results indicating the utility of this type of design after further optimization.
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