We have developed a simple microchip-based method for the separation and enrichment of acetylated proteins and peptides using a microchip technique. Poly (dimethylsiloxane) (PDMS) microfluidic channels were modified by passing an acidic solution of hydrogen peroxide through them. This resulted in hydrophilic silanol-covered surfaces onto which poly (diallyldimethylammonium chloride) (PDDA) can be coated. Protein A/G beads were then captured by the PDDA layer and antibodies can then be immobilized via the protein A/G. This technique enables efficient capture of antigens due to the optimal spacing and orientation of surface molecules. Two solutions, one containing 72.5 fmol μL−1 of acetylated bovine serum albumin (BSA-Ac), the other 72.5 fmol μL−1 of tryptic BSA-Ac digest were then enriched. High selectivities were obtained, and a 82.4 % recovery of the acetylated proteins was attained. This on-chip platform was then coupled to MALDI-MS to provide information on the acetylation sites of proteins and peptides. Additional peaks were observed in the mass spectra after enrichment and were assigned to acetylated peptides. This is significant with respect to understanding the mechanism and function of acetylation. In our opinion, this microchip-based technique has a large potential for detecting acetylated proteins and peptides in complex biological mixtures, and in acetylomics in general.

•The impact of glutathiolation on HbA1c measurement was demonstrated quantitatively.•The focused location of GSH-HbA1c complex in cIEF was confirmed.•Systematical identification and quantitative analysis of the GSH-HbA1c.•The comprehensive HPLC-cIEF-ESI/MS-ELISA strategy.•Impact evaluation of the complex on HbA1c measurement for diabetes screening.Hemoglobin A1c (HbA1c) has been proven to be a key biomarker for diabetes screening, and glutathiolation of HbA1c (viz., GSS-HbA1c) has been identified. However, the impact of GSS-HbA1c on the measurement of HbA1c for diabetes screening has not been quantitatively assessed yet. To address the issue, the micropreparative capillary isoelectric focusing (cIEF) developed in our previous work was used for the high resolution separation and purification of hemoglobin (Hb) species. The main fractions of HbA0, HbA3 and HbA1c extracted from the developed cIEF were identified by validated Mono S method. The proposed GSS-HbA1c fractions in the cIEF were pooled and identified by electrospray ionization mass spectrometry (ESI-MS). The HbA1c enzyme-linked immunosorbent assay (ELISA) kit was employed for further quantitative analysis of GSS-HbA1c. A total of 34 blood samples with HbA1c levels from 4.2% to 13.4% were assessed via the above comprehensive strategy of IEF-HPLC-MS-ELISA. It was demonstrated that the HbA1c levels detected by cation exchange LC were considerably influenced by the glutathiolation of Hb and the range of detected GSS-HbA1c values was between 0.23% and 0.74%. The results and developed cIEF methods have considerable significances for investigation of diabetes and clinical diagnosis.