Analysis of antibody-drug conjugates by comprehensive on-line two-dimensional hydrophobic interaction chromatography x reversed phase liquid chromatography hyphenated to high resolution mass spectrometry. I - Optimization of separation conditions.

Antibody-drug-conjugates (ADCs) manufacturing leads to a mixture of species which needs to be characterized during development and for further quality control. The coupling of on-line HIC x RPLC to high resolution mass spectrometry can be considered as a very efficient analytical method, providing extensive information on ADC sample, within a reduced time scale. Our intention in this first paper is to present the approach used to rationally optimize the numerous conditions that can affect the quality of the 2D-separation. HIC and RPLC conditions were therefore optimized to prevent salt precipitation due to solvent mixing and to enhance sensitivity, while limiting the total analysis time. We demonstrated that adding salt in the sample solvent before HIC injection allows a significant peak shape improvement. The gradient profile was also carefully optimized in both dimensions, leading to a two-step gradient in HIC and bracketed gradient in RPLC. This study shows that on-line HIC x RPLC hyphenated to high resolution mass spectrometry is a useful method to obtain rapid and extensive structural information on the peaks observed in the first HIC dimension, thereby leading, in a single step requiring 75min, to the precise determination of the average drug-to-antibody ratio (DAR) by HIC as well as the knowledge of the drug load distribution for a particular DAR. The structural characterization of ADC fragments by RPLC-QTOF will be discussed in the second part of this two-part series.

Potential and limitations of on-line comprehensive reversed phase liquid chromatography×supercritical fluid chromatography for the separation of neutral compounds: An approach to separate an aqueous extract of bio-oil.

On-line comprehensive Reversed Phase Liquid Chromatography×Supercritical Fluid Chromatography (RPLCxSFC) was investigated for the separation of complex samples of neutral compounds. The presented approach aimed at overcoming the constraints involved by such a coupling. The search for suitable conditions (stationary phases, injection solvent, injection volume, design of interface) are discussed with a view of ensuring a good transfer of the compounds between both dimensions, thereby allowing high effective peak capacity in the second dimension. Instrumental aspects that are of prime importance in on-line 2D separations, were also tackled (dwell volume, extra column volume and detection). After extensive preliminary studies, an on-line RPLCxSFC separation of a bio-oil aqueous extract was carried out and compared to an on-line RPLCxRPLC separation of the same sample in terms of orthogonality, peak capacity and sensitivity. Both separations were achieved in 100min. For this sample and in these optimized conditions, it is shown that RPLCxSFC (with Hypercarb and Acquity BEH-2EP as stationary phases in first and second dimension respectively) can generate a slightly higher peak capacity than RPLCxRPLC (with Hypercarb and Acquity CSH phenyl-hexyl as stationary phases in first and second dimension respectively) (620 vs 560). Such a result is essentially due to the high degree of orthogonality between RPLC and SFC which may balance for lesser peak efficiency obtained with SFC as second dimension. Finally, even though current limitations in SFC instrumentation (i.e. large extra-column volume, large dwell volume, no ultra-high pressure) can be critical at the moment for on-line 2D-separations, RPLCxSFC appears to be a promising alternative to RPLCxRPLC for the separation of complex samples of neutral compounds.