Nanoelectrospray mass spectrometry, the infusion at low flow rates of unseparated peptide mixtures representing protein proteolytic digests into an electrospray ionization mass spectrometer (MS), has been shown to be a suitable method for the analysis of small amounts of proteins. However, the current technique is time consuming, tedious, and difficult to automate. We used microfabrication technologies to construct a device for the sequential infusion of different peptide samples into an electrospray ionization MS without the need for sample manipulation. In this device, etched sample and buffer reservoirs are connected via etched channels to microelectrospray ion source. Peptide samples, typically unseparated tryptic digests of proteins, are applied to different reservoirs. A flow of liquid originating from a specific reservoir is generated and selectively directed toward the microsprayer and the MS by electroosmotic pumping. The analyte proteins are identified by searching sequence databases with the information contained in the collision-induced spectra of selected peptides. With this system, we have achieved a limit of detection in the low femtomoles per microliter range for peptide standards. We also show that samples deposited in different reservoirs can be sequentially mobilized without cross-contamination and that proteins can be conclusively identified at the low femtomoles per microliter level. The successful coupling online of microfabricated devices to an electrospray ionization MS represents an essential step toward the construction of automated, high-throughput, and high-sensitivity analytical systems.
The combination of microfabricated fluidic systems (μFAB) and electrospray mass spectrometers (ESI‐MS) will provide multiplexed and integrated analytical systems for proteins and other biomolecules. Implementation of this novel approach requires the development of robust and user‐friendly μFAB devices. Here, we present new approaches that improve the robustness, user friendliness and performance of μFAB devices coupled to MS. First, we present the development of a convenient mount to connect a μFAB device to the ESI‐MS and the incorporation of filters in the reservoirs and exit of the μFAB. This mount facilitates interfacing and significantly reduces the chemical noise observed by the MS. Furthermore, we demonstrate improvements in sample handling and delivery by using either a nonaqueous electrolyte or a cationic coating on the surfaces in the μFAB device and transfer capillary. These improvements are applied to protein analysis by continuous infusion of proteolytic digests.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.