The proliferation of increasingly more sophisticated analytical separation systems, often incorporating increasingly more powerful detection techniques, such as highresolution mass spectrometry, causes an urgent need for highly efficient dataanalysis and optimization strategies. This is especially true for comprehensive twodimensional chromatography applied to the separation of very complex samples. In this contribution, the requirement for chemometric tools is explained and the latest developments in approaches for (pre-)processing and analyzing data arising from oneand two-dimensional chromatography systems are reviewed. The final part of this review focuses on the application of chemometrics for method development and optimization.
The majority of liquid chromatography (LC) methods are
still developed
in a conventional manner, that is, by analysts who rely on their knowledge
and experience to make method development decisions. In this work,
a novel, open-source algorithm was developed for automated and interpretive
method development of LC(−mass spectrometry) separations (“AutoLC”).
A closed-loop workflow was constructed that interacted directly with
the LC system and ran unsupervised in an automated fashion. To achieve
this, several challenges related to peak tracking, retention modeling,
the automated design of candidate gradient profiles, and the simulation
of chromatograms were investigated. The algorithm was tested using
two newly designed method development strategies. The first utilized
retention modeling, whereas the second used a Bayesian-optimization
machine learning approach. In both cases, the algorithm could arrive
within 4–10 iterations (i.e., sets of method
parameters) at an optimum of the objective function, which included
resolution and analysis time as measures of performance. Retention
modeling was found to be more efficient while depending on peak tracking,
whereas Bayesian optimization was more flexible but limited in scalability.
We have deliberately designed the algorithm to be modular to facilitate
compatibility with previous and future work (e.g., previously published data handling algorithms).
The great potential gains in separation power and analysis time that can result from rigorously optimizing LC-MS and 2D-LC-MS methods for routine measurements has prompted many scientists to develop computer-aided method-development tools. The applicability of these has been proven in numerous applications, but their proliferation is still limited. Arguably, the majority of LC methods are still developed in a conventional manner, i.e. by analysts who rely on their knowledge and experience. In this work, a novel, open-source algorithm was developed for automated and interpretive method development of LC separations. A closed-loop workflow was constructed that interacted directly with the LC and ran unsupervised in an automated fashion. The algorithm was tested using two newly designed strategies. The first utilized retention modeling, whereas the second used the Bayesian-optimization machine-learning approach. In both cases, the algorithm could arrive within ten iterations at an optimum of the objective function, which included resolution and measurement time. The design of the algorithm was modular, so as to facilitate compatibility with previous works in literature and its performance thus hinged on each module (e.g., signal processing, choice of retention model, objective function). Key focus areas for further improvement were identified. Bayesian optimization did not require any peak tracking or retention modeling. Accurate prediction of elution profiles was found to be indispensable for the strategy using retention modeling. This is the first interpretive algorithm demonstrated with complex samples. Peak tracking was conducted using UV-Vis absorbance detection, but use of MS detection is expected to significantly broaden the applicability of the workflow.
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