Abstrakt
We report on the optimization of nano-LC gradient separations of proteomic samples that vary in complexity. The gradient performance limits were visualized by kinetic plots depicting the gradient time needed to achieve a certain peak capacity, while using the maximum system pressure of 80 MPa.
The selection of the optimal particle size/column length combination and corresponding gradient steepness was based on scouting the performance of 75 mu m id capillary columns packed with 2, 3, and 5 mu m fully porous silica C18 particles. At optimal gradient conditions, peak capacities up to 500 can be obtained within a 120 min gradient using 2 mu m particle-packed capillary columns.
Separations of proteomic samples including a cytochrome c tryptic digest, a bovine serum albumin tryptic digest, a six protein mix digest, and an Escherichia coli digest are demonstrated while operating at the kinetic-performance limit, i.e. using 2-mu m packed columns, adjusting the column length and scaling the gradient steepness according to sample complexity. Finally, good run-to-run retention time stability (RSD values below 0.18%) was demonstrated applying ultra-high pressure conditions.