Effect of Sampling Rate and Data Pretreatment for
Targeted and Nontargeted Analysis by Means of Liquid Chromatography
Coupled to Drift Time Ion Mobility Quadruple Time-of-Flight Mass Spectrometry
posted on 2021-09-13, 15:05authored byKristina Tötsch, John C. Fjeldsted, Sarah M. Stow, Oliver J. Schmitz, Sven W. Meckelmann
Ion mobility as an
additional separation dimension can help to
resolve and annotate metabolite and lipid biomarkers and provides
important information about the components in a sample. Identifying
relevant information in the resulting data is challenging because
of the complexity of the data and data evaluation strategies for both
targeted or nontargeted workflows. Frequently, feature analysis is
used as a first step to search for differences between samples in
discovery workflows. However, follow-up experimentation often leads
to more targeted data extraction methods. In both cases, optimizing
data sets for data extraction can make an important contribution to
the overall results. In this work, we evaluate the effect of experimental
conditions including acquisition sampling rate and data pretreatment
on lipid standards and lipid extracts as examples of complex biological
samples analyzed by liquid chromatography coupled to drift time ion
mobility quadrupole time-of-flight mass spectrometry. The results
show that a reduction of both peak variation and background noise
can be achieved by optimizing the sampling rate. The use of data pretreatment
including data smoothing, intensity thresholding, and spike removal
also play an important role in improving detection and annotation
of analytes from complex biological samples, whereas nonoptimal data
sampling rates and preprocessing can lead to adverse effects including
the loss or alternation of small, or closely eluting, low-abundant
peaks.