Spatial profiling of stapled α–helical peptide ATSP-7041 in mouse whole-body thin tissue sections using droplet-based liquid microjunction surface sampling-HPLC-ESI–MS/MS.

Graphical abstract Highlights • The application of an autosampler/HPLC-ESI–MS/MS system for spatially resolved quantitative surface sampling/profiling of ATSP-7041. • The observed ATSP-7041 concentration was lower than that measured by the tissue punch workflow at the same tissue location of a serial section. • Calculated extraction efficiencies were reproducible within a given organ. • Reproducibility of the approach could provide a non-labor intensive and high-throughput means to acquire spatially resolved quantitative data. Abstract The application of a fully automated autosampler/HPLC-ESI–MS/MS system for spatially resolved quantitative droplet-based liquid extraction surface sampling/profiling of stapled α–helical peptide ATSP-7041 in mouse whole-body thin tissue sections is reported. 20-μm-thick serial tissue sections of an ATSP-7041 dosed mouse were prepared and the absolute concentration of the targeted peptide was first determined in different organs using 2.3-mm diameter tissue punches, standard bulk tissue extraction protocols, and subsequent HPLC separation and tandem mass spectrometric analysis. The same organs/locations were then analyzed in neighboring tissue sections using the droplet-based surface sampling approach. The observed ATSP-7041 concentration using this method was always significantly lower than that measured by the tissue punch workflow at the same tissue location of a serial section. Calculated extraction efficiencies were 10.7 ± 0.5% (brain), 11.0 ± 3.2% (liver spot 1), 10.7 ± 2.6% (liver spot 2), 15.0 ± 0.6% (lung) and 12.9 ± 0.7% (blood). While these extraction efficiency values were low, they were reproducible within a given organ. This suggests that once the extraction efficiency is established for a given tissue type and drug, the reproducibility of the droplet-based approach could provide a non-labor intensive and high-throughput means to acquire spatially resolved quantitative analysis of multiple samples of the same type. [ABSTRACT FROM AUTHOR]