Thiol-ene microfluidic chip for fast on-chip sample clean-up, separation and ESI mass spectrometry of peptides and proteins.

Mass spectrometry (MS) is a key technology for sensitive and high-resolution mass analysis of peptides and proteins. Sample clean-up and chromatographic separation is typically performed prior to MS analysis to limit adduct formation and ionization suppression. Usually, this requires a high-pressure LC pump system equipped with expensive metal chromatographic columns placed in-line of an electrospray ionization (ESI) source. Microfluidic devices coupled to MS have gained considerable attention, due to the promise of low manufacturing costs, low sample consumption and channels with a high surface area to volume ratio and tailorable functional groups. Here, we describe a thiol-ene microfluidic chip capable of fast chromatographic sample clean-up, concentration, and separation of complex protein and peptide mixtures with direct on-chip ESI. On-chip reversed-phase chromatography (RPC) was performed through an in-situ polymerized monolith frit for retaining inexpensive commercially available reversed-phase (RP) spherical particles, while on-chip ESI is achieved through an emitter monolithically implemented by precision micro milling. The on-chip integration of both RPC and ESI emitter allowed for a minimization of dead-volumes and enables very fast sample clean-up, efficient ionization, and mass analysis of peptides and proteins from complex matrices.

Thiol-ene Microfluidic Chip for Performing Hydrogen/Deuterium Exchange of Proteins at Subsecond Time Scales.

Hydrogen/deuterium exchange monitored by mass spectrometry (HDX-MS) has become a routine approach for sensitive analysis of the dynamic structure and interactions of proteins. However, transient conformational changes and weak affinity interactions found in many biological systems typically only perturb fast-exchanging amides in proteins. Detection of HDX changes for such amides require shorter deuterium labeling times (subsecond) than can be performed reproducibly by manual sample handling. Here, we describe the development and validation of a microfluidic chip capable of rapid on-chip protein labeling and reaction quenching. The fastHDX thiol-ene microchip is fabricated entirely using thiol-ene photochemistry. The chip has a three-channel design for introduction of protein sample, deuterated buffer, and quench buffer. Thiol-ene based monolith plugs (i.e., polymerized thiol-ene emulsions) situated within microchannels are generated in situ using a 3D-printed photolithography mask. We show that efficient on-chip mixing can be achieved at channel junctions by spatially confined in-channel monolith mixers. Using human hemoglobin (Hb), we demonstrate the ability of the chip to perform highly reproducible HDX in the 0.14-1.1 s time frame. The HDX of Hb at 0.14-1.1 s, resolved to peptide segments, correlates closely with structural features of the crystal structure of the Hb tetramer, with helices exhibiting no or minor HDX and loops undergoing pronounced HDX even at subsecond time scales. On-chip HDX of Hb at time points ranging from 0.14-1.1 s demonstrates the ability to distinguish fast exchanging amides and thus provides enhanced detection of transient structure and interactions in dynamic or exposed regions of proteins in solution.

Thiol-ene Monolithic Pepsin Microreactor with a 3D-Printed Interface for Efficient UPLC-MS Peptide Mapping Analyses.

To improve the sample handling, and reduce cost and preparation time, of peptide mapping LC-MS workflows in protein analytical research, we here investigate the possibility of replacing conventional enzymatic digestion methods with a polymer microfluidic chip based enzyme reactor. Off-stoichiometric thiol-ene is utilized as both bulk material and as a monolithic stationary phase for immobilization of the proteolytic enzyme pepsin. The digestion efficiency of the, thiol-ene based, immobilized enzyme reactor (IMER) is compared to that of a conventional, agarose packed bed, pepsin IMER column commonly used in LC-MS based protein analyses. The chip IMER is found to rival the conventional column in terms of digestion efficiency at comparable residence time and, using a 3D-printed interface, be directly interfaceable with LC-MS.