The efficient profiling of serum N-linked glycans by a highly porous 3D graphene composite.

In this work, an enrichment approach for the profiling of N-linked glycans was developed by utilizing a highly porous 3D graphene composite fabricated from graphene oxide nanosheets and a phenol-formaldehyde polymer via graphitization and KOH activation. In tailoring the large surface area (ca. 2213 m2 g-1) and 3D-layered mesoporous structure, the 3D graphene composite demonstrated not only high efficiency in glycan enrichment but also the size-exclusion effect against residual protein interference. For a standard protein ovalbumin digest, 26 N-linked glycans were identified with good repeatability, and the detection limit was as low as 0.25 ng µL-1 with the identification of 13 N-linked glycans (S/N > 10). When the mass ratio of the ovalbumin digest to the interfering proteins, i.e., bovine serum albumin and ovalbumin was 1 : 2000 : 2000, 18 N-linked glycans could still be detected with sufficient signal intensities. From a 60 nL minute complex human serum sample, up to 53 N-linked glycans with S/N > 10 were identified after the 3D graphene enrichment, while only 20 N-linked glycans were identified by the porous graphitized carbon material used for comparison. In addition, the application of the 3D graphene composite in profiling the up-regulated and down-regulated N-linked glycans from the real clinical serum samples of ovarian cancer patients confirmed the potential of the 3D graphene composite for analyzing minute and complicated biological samples.

Synthesis and evaluation of sulfobetaine zwitterionic polymer bonded stationary phase.

Zwitterionic polymer stationary phases have attracted increasing attention in hydrophilic interaction chromatography (HILIC). In this work, a zwitterionic sulfobetaine functionalized polyacrylamide stationary phase (named TENS) based on porous silica particles was prepared via controlled surface initiated reversible addition-fragmentation transfer (RAFT) polymerization. Instead of traditional methacrylate type sulfobetaine monomer, acrylamide type sulfobetaine monomer, which has higher chemical stability and hydrophicility, was employed in this work. The characterization of elemental analysis and solid-state 13C cross polarization/magic-angle-spinning nuclear magnetic resonance indicated the successful preparation of TENS stationary phase. Meanwhile, scanning electron microscope (SEM), nitrogen adsorption experiment and study of size exclusion performance were conducted, revealing that the surface initiated polymerization was well controlled. For better understanding of TENS material under HILIC mode, chromatographic evaluation of TENS material was performed, among which, TENS material exhibited good hydrophilicity and chemical stability. To further study the applicability of TENS material, saccharides which were considered as challenging targets in HILIC, were chosen as tested analytes. Various saccharide samples, including fructooligosaccharide, trisaccharide isomers and ginsenosides, were well separated on TENS material. Moreover, TENS material displayed good selectivity for the enrichment of glycopeptides. These results demonstrated the capability of TENS as a promising material in glycomics and glycoproteomics.

A controlled thiol-initiated surface polymerization strategy for the preparation of hydrophilic polymer stationary phases.

A controlled thiol-initiated surface polymerization strategy has been successfully developed and employed to prepare hydrophilic polymer stationary phases, which exhibited excellent chromatographic performance and protein non-fouling properties.

A novel ionic-bonded cellulose stationary phase for saccharide separation.

A hydrophilic interaction liquid chromatography (HILIC) stationary phase of cellulose-coated silica was synthesized as a novel saccharide separation material. The material, prepared with a method based on ionic interaction, was demonstrated to be efficient for immobilization of saccharides on silica supports. The method is more efficient than traditional immobilized saccharide stationary phase synthesis methods. It was evolved from a method using anion exchanger microparticles agglomerated onto macroparticles of cation exchangers to produce anion exchangers. Cationic cellulose, which has a large number of hydroxyl groups, was immobilized on sulfonated silica. The cellulose-coated stationary phase we designed used strong hydrogen bonding between cellulose hydroxyl and carbohydrate compounds for HILIC retention and separation. The stationary phase was successfully used to separate the samples of polar compounds and the complex samples of oligosaccharides, and demonstrated good reproducibility and stability. The material exhibited good separation selectivity for carbohydrates and ability to enrich glycosylated peptides. The method described here is easy to achieve, environmentally safe and innovative than other methods. It also has extensive application possibilities to separate other categories polar compounds.