Analysis of Isocratic Chromatographic Retention Data using Bayesian

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Analysis of Isocratic Chromatographic Retention Data using Bayesian Multilevel Modeling #ukasz Kubik, Roman Kaliszan, and Pawel Wiczling Anal. Chem., Just Accepted Manuscript • DOI: 10.1021/acs.analchem.8b04033 • Publication Date (Web): 18 Oct 2018 Downloaded from http://pubs.acs.org on October 22, 2018

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Analytical Chemistry

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Analysis of Isocratic Chromatographic Retention Data using

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Bayesian Multilevel Modeling

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Łukasz Kubik, Roman Kaliszan, Paweł Wiczling*

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Department of Biopharmaceutics and Pharmacodynamics, Medical University of Gdańsk, Gen. J.

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Hallera 107, 80-416 Gdańsk, Poland

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*Corresponding author's e-mail: [email protected]

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Abstract

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The objective of this work was to develop a multilevel (hierarchical) model based on isocratic

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reversed phase high-performance chromatographic data, collected in methanol and acetonitrile for

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58 chemical compounds. Such multilevel model is a regression model of the analyte-specific

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chromatographic measurements, in which all the regression parameters are given a probability

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model. It is a fundamentally different approach from the most common approach where parameters

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are separately estimated for each analyte (without sharing information across analytes and different

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organic modifiers).

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The statistical analysis was done with Stan software implementing the Bayesian statistics

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inference with Markov Chain Monte Carlo sampling. During the model building process a series

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of multilevel models of different complexity were obtained, such as: 1) model with no pooling

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(separate models are fitted for each analyte); 2) model with partial pooling (a common distribution

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for analyte-specific parameters); and 3) model with partial pooling and a regression model relating

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analyte-specific parameters and analyte-specific properties (QSRR equations). All the models were

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compared with each other using 10-fold cross-validation.

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The benefits of multilevel models in inference and predictions were shown. In particular the

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obtained models allowed us to i) better understand the data and ii) to solve many routine analytical

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problems, e.g. to obtain a well-calibrated predictions of retention factor for an analyte in

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acetonitrile-containing mobile phases given no, one or several measurements in methanol-

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containing mobile phases and vice versa.

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Keywords

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multi-level modeling, Bayesian statistics, liquid chromatography, QSRR

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Analytical Chemistry

1. Introduction

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The retention mechanism in the reversed-phase high-performance liquid chromatography

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(RP HPLC) is a complicated process involving a great variety of interactions that are difficult to

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describe exactly1. Generally, the retention factor depends on the properties of the mobile phase, the

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stationary phase and the analyzed compounds, e.g. polar and non-polar surface area of analytes,

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dielectric constant of the mobile phase, surface properties of the packing material and other

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descriptors2. The complex nature of these interactions usually requires mathematical models to

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quantify the relationship between retention time and multiple method parameters, such as pH,

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temperature, buffer concentration and other conditions1,3. Such a model, when appropriately

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validated, can be of great help during method development procedure by giving an analyst means

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to predict chromatograms for a wide range of experimental conditions.

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Models used in the field of chromatography are often build to describe the behavior of a

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single analyte (or for a set of analytes, modeled one at a time). Such models are certainly useful

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and serve its role in solving many problems encountered in the laboratory4-7. In this work we would

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like to provide a generalization of these models to multilevel (hierarchical) models, that could even

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further increase the role of predictive modeling in the field of chromatography. The basic idea is

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to take into account similarities between analytes, solvents or columns while developing a

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chromatographic model. As an example let us consider the case of isocratic chromatographic data

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collected for methanol (MeOH) and acetonitrile (ACN) containing mobile phases for a diverse set

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of analytes. One would generally approach this data by building a separate models for each analyte

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either for MeOH or ACN. And then eventually seek for a relationship between analyte-specific

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chromatographic parameters, such as log kw, and analyte properties, such as log P or polar surface

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area (QSRR equations). It is not an optimal approach as there is a lot of information that could be

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shared, both between analytes and the organic modifiers, e.g. the same log kw values regardless of

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organic modifier type or similarity of log kw values for analytes having similar log P values.

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Multilevel model is a regression model of the individual (analyte-specific) chromatographic

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measurements, in which all the model parameters – regression coefficients – are also given a

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probability model. This second-level parameters are also estimated from the data. Multilevel

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modeling is well known and commonly used mathematical technique, applied in many fields, e.g.

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in cancer studies8, anesthesiology9 or educational research10. It is still not a common tool for

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retention prediction; however, the Bayesian inference itself was reported to be a useful approach

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in chromatography11-13. Recently multilevel modeling using Stan software was described as a

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convenient method for describing gradient HPLC data14.

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In this work we re-analyzed an isocratic RP HPLC data previously obtained in our

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department15 for 58 chemical compounds. During the model building process a series of models of

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different complexity were proposed and compared, such as: 1) model with no pooling (separate

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models were fitted for each analyte); 2) model with partial pooling (a common distribution for

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analyte-specific parameters); and 3) model with partial pooling and a regression model between

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analyte-specific parameters and analyte-specific properties (QSRR equations). Multilevel models

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were implemented in the Stan software that provides full Bayesian inference for continuous-

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variable models through Markov Chain Monte Carlo (MCMC) methods. The predictive

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performance of the proposed models was evaluated using the posterior predictions, Watanabe-

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Akaike Information Criterion (WAIC) and 10-fold cross-validation. We also illustrate the

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usefulness of the proposed models in predicting retention times in ACN-containing mobile phases

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given no, one or several measurements in MeOH-containing mobile phases and vice versa.

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2. Experimental Section

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2.1 Chromatographic parameters

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The data used to illustrate the main concept of multilevel models is taken from Al-Haj et

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al. article15. It was obtained using RP HPLC in the isocratic retention mode, with the UV detection.

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58 drug-like chemical compounds, listed in the Supporting Information, were analyzed. The

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analytes had lipophilicity (MLOGP) that ranged from -0.2 to 5.1 and molecular mass that range

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from 78 to 270 g/mol. MeOH and ACN were used as a mobile phase. The percent amount of

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organic modifier in the mobile phase (φ) equaled 20, 25, 30, 35, 40, 45, 50, 60, 65, 70, 75, 80, 85,

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90, 95 and 20, 25, 30, 40, 50, 60, 65, 70, 75, 80 for MeOH and ACN, respectively. For more details

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it is advised to study the original article. The raw data is attached in the Supporting Information. It

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is also presented graphically in Supporting Figure S1.

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2.2 Molecular modeling

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In the original work15, for each analyte a set of structural descriptors was calculated using

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the HyperChem software16. Three descriptors were used in modeling: total dipole moment (µ),

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Analytical Chemistry

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maximum electron excess on a most charged atom (δmin) and water-accessible molecular surface

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area (AWAS).

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Additionally, all 58 compounds were re-modelled using respectively: Open Babel 2.3.217

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(SMILES to MOL2 conversion), Discovery Studio Visualizer 1618 (preliminary geometry

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optimization using Dreiding-like forcefield17), GaussView 3.0920 (Gaussian input files preparation)

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and Gaussian 0921 software (B3LYP method), with the application of the 6-31G basis set (final

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structure optimization). Only 4-iodophenol was optimized using STO-6G set, due to the occurrence

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of the iodine atom. Dragon 722 software was used to calculate the MLOGP and molar weight.

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2.3 Multilevel modeling

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Multilevel modeling was carried out using the Stan23 / CmdStan 2.1624 software linked with

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the Matlab® R2017b25 using the MatlabStan 2.1526. For the calculation of each model we used the

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following values of the Stan parameters: number of iterations = 1000, warmup = 1000, number of

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Markov chains = 4. Stan codes were based on the Margossian and Gillespie work27,28. Exemplary

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Stan code can be found in the Supporting Information. Determination of model parameters provides

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a possibility to obtain predictions (and uncertainty around these predictions) for a new (not-yet-

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analyzed) analyte that take into account the information about the likely values of analyte-specific

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parameters (from the posterior distribution) and any set of experimental data. To assess the

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accuracy of such predictions, posterior predictive checks were used. Such predictive checks are

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simply a replicated dataset using the model interference in the forward directions. These replicated

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data sets, when compared visually with the original data, allow to assess model fit and predictive

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capabilities of the model29. The predictive power of models were assessed with the Watanabe-

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Akaike Information Criterion (WAIC), using the MatlabStan command mstan.waic. WAIC is

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conceptually similar to Akaike information criterion (AIC) and Bayesian information criterion

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(BIC), where the higher the WAIC value, the better the model predictive performance. Since the

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WAIC is not able to assess the model performance for new analytes (it approximates leave-one-

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measurement-out cross-validation), a 10-fold cross-validation (specifically leave-analytes-out

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cross-validation) was used instead. The analytes from the original data were randomly partitioned

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into 10 subsamples. Of the 10 subsamples, a single subsample was excluded from the analysis.

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The remaining 9 subsamples plus none or limited number of measurements from the excluded

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analytes were used to obtain predictions for those excluded analytes. The cross-validation process

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was then repeated 10 times, with each of the 10 subsamples used exactly once as the validation

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data. The results from the folds were combined and summarized as an log pointwise predictive

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density of cross validation (LPDCV) and root mean square error of cross validation (RMSECV).

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The LPDCV is a preferred way to evaluate the predictive accuracy of a Bayesian model. RMSECV

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is less appropriate for models that are far from the normal distribution. The details on how WAIC,

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LPDCV, RMSECV were calculated are provided in the Supplementary Information and

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reference30. 6 scenarios were considered during the cross-validation depending on the number of

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measurements available for predictions: 1) no measurements (NONE); 2) single MeOH

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measurement (1M); 3) single ACN measurement (1A); 4) single MeOH and single ACN

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measurement (1M & 1A); 5) all ACN measurements (AllA) and 6) all MeOH measurements

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(AllM). They allowed us to assess the uncertainty of predictions in the situation of having access

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to the limited number of experimental data.

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3. Model development procedure

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3.1 The classical approach proposed by Al-Haj et al.15

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In the original approach presented by Al-Haj et al 15, a separate models were fitted for each

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analytes. The structural model assumed a simple Snyder-Soczewiński model for MeOH and ACN

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that can be described by the following equation:

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𝑙𝑜𝑔𝑘𝑖𝑗𝑘 = 𝑙𝑜𝑔𝑘𝑤, 𝑖𝑘 ― 𝑆1,𝑖𝑘 ∙ 𝜑𝑗

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where j = 1... J (out of J) denotes jth mobile phase compositions; i = 1… nAnalytes denotes ith (out

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of nAnalytes) analyte, and k = 1..2 denotes MeOH (k = 1) or ACN (k = 2); log kw,ik denotes a

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chromatographic measure of hydrophobicity (analyte and organic modifier specific). It is basically

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a retention factor corresponding to the zero content of the organic modifier (i.e. neat water); and

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S1,ik is the slope coefficient (also analyte and organic modifier specific) that can be understood as

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an apparent difference of retention factors in water and MeOH or ACN.

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The observed retention factors (log kObs) was further modeled according to:

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𝑙𝑜𝑔𝑘𝑂𝑏𝑠,[𝑧] ~ 𝑁(𝑙𝑜𝑔𝑘𝑖[𝑧]𝑗[𝑧]𝑘[𝑧], 𝜎𝑖[𝑧]𝑘[𝑧])

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Where, z = 1…nObs denotes zth (out of nObs) measurement; N denotes the normal distribution

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with the mean given be Eq. (1) and standard deviation σik; a tilde (~) denotes "has the probability

Eq. 1

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Eq. 2

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Analytical Chemistry

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distribution of", i.e. the values of logkObs are randomly drawn from the given (in this case normal)

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distribution. Standard deviations are conventionally assumed to be analyte and organic modifier

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specific.

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In the next modeling step the QSRR relationship were proposed separately for log kw,i1 and log kw,i2

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by assuming a linear relationship between log kw and a set of predictors (descriptors) (e.g.

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lipophilicity (log P) or total dipole moment (µi), maximum electron excess on a most charged atom

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(δmin,i) and water-accessible molecular surface area (AWAS,i)):

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log kw,ik~𝑁(𝜃𝑙𝑜𝑔𝑘𝑤 + 𝛽1,𝑘𝑙𝑜𝑔𝑃𝑖,𝜔𝑙𝑜𝑔𝑘𝑤)

Eq. 3

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log kw,ik~𝑁(𝜃𝑙𝑜𝑔𝑘𝑤 + 𝛽1,𝑘𝜇𝑖 + 𝛽2,𝑘𝛿𝑚𝑖𝑛,𝑖 + 𝛽3,𝑘𝐴𝑊𝐴𝑆,𝑖,𝜔𝑘𝑙𝑜𝑔𝑘𝑤)

Eq. 4

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where θlogkw,k is a retention factor for an analyte with descriptors equal to zero, ω is the scale

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parameter and β1,k-β3,k are regression coefficients (different for MeOH and ACN).

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There are several weaknesses of such a modeling approach: i) log kw is assumed to be

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different for MeOH and ACN, ii) two independent QSRR equations for log kw were proposed for

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MeOH and ACN, iii) the QSRR equations for other parameters (e.g. for S1,ik) were not explored,

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iv) the two-stage approach (the estimation of QSRR equations conditional on the estimated log kw,i

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values) does not properly take into account the uncertainty of log kw,ik. Please note it has different

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uncertainty depending on the degree of extrapolation, v) finally the correlations between analyte-

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specific parameters were not explored. There is no need to make such simplifications during the

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model building process as shown in the subsequent sections.

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3.2 Model with partial pooling (a common distribution for analyte-specific parameters)

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Further we will assume a more realistic non-linear relationship between the log k and

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organic modifier (Neue et al31 equation):

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𝑙𝑜𝑔𝑘𝑖𝑗𝑘 = 𝑙𝑜𝑔𝑘𝑤,𝑖 ― 1 + 𝑆2,𝑖𝑘 ∙ 𝜑𝑗

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where S2,ik is the curvature coefficient for ith analyte for MeOH (k = 1, equivalent notation S2m,i)

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and ACN (k = 2, equivalent notation S2a,i). Please note that the log kw is the same for MeOH and

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ACN, as it should be. For convenience, this equation was reparametrized to the retention factor in

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MeOH and ACN (log km and log ka) noticing that:

𝑆1,𝑖𝑘 ∙ 𝜑𝑗

Eq. 5

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𝑆1,𝑖1

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𝑙𝑜𝑔𝑘𝑚,𝑖 = 𝑙𝑜𝑔𝑘𝑤,𝑖 ― 1 + 𝑆2,𝑖1

Eq. 6

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𝑙𝑜𝑔𝑘𝑎,𝑖 = 𝑙𝑜𝑔𝑘𝑤,𝑖 ― 1 + 𝑆2,𝑖2

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Hence, the retention factor in neat MeOH and ACN has a more natural interpretation than the slope.

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The observed retention factors (log kObs) was further modeled similarly as previously:

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𝑙𝑜𝑔𝑘𝑂𝑏𝑠,𝑧 ~ 𝑁(𝑙𝑜𝑔𝑘𝑖[𝑧]𝑗[𝑧]𝑘[𝑧],𝜎)

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where, z denotes zth measurement; N denotes the normal distribution with the mean given by Eq.

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(1) and standard deviation σ. This time a common standard deviation is used. This assumptions can

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be relaxed if needed.

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The idea of multilevel modeling allows to provide a range of second-level models for analyte-

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specific parameters (log kw,i, log km,i, log ka,i, ln S2m,i, ln S2a,i):

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[ ] ( )

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where MST denotes the multivariate student t distribution, θ is a mean value of the parameter,  is

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a normality parameter, and  denotes a variance-covariance matrix. In particular θlogkw, θlogkm,

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θlogka, θlnS2m, θlnS2a denote typical values of parameters. The use of multivariate distribution allows

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to model the correlation between analyte-specific parameters. Please note that some correlations

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(especially between log kw,i, log km,i and log ka,i) are expected in chromatographic system. The S2m

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and S2a were modeled on a logarithmic scale to ensure their positive values.

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The model for log kObs is the same as previously. The following priors were assigned based on

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literature findings and our judgment and are part of model assumptions:1, 32,33

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θlogkw ~ N(2, 5)

Eq. 10

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θlogkm ~ N(0, 5)

Eq. 11

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θlnS2m ~ N(ln(0.2), 0.5)

Eq. 12

𝑆1,𝑖2

Eq. 7

Eq. 8

𝑙𝑜𝑔𝑘𝑤,𝑖 𝜃𝑙𝑜𝑔𝑘𝑤 𝑙𝑜𝑔𝑘𝑚,𝑖 𝜃𝑙𝑜𝑔𝑘𝑚 𝑙𝑜𝑔𝑘𝑎,𝑖 ~𝑀𝑆𝑇 , 𝜃𝑙𝑜𝑔𝑘𝑎 ,𝛺 𝑙𝑛𝑆2𝑚,𝑖 𝜃𝑙𝑛𝑆2𝑚 𝑙𝑛𝑆2𝑎,𝑖 𝜃𝑙𝑛𝑆2𝑎

Eq. 9

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Analytical Chemistry

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θlogka ~ N(0, 5)

Eq. 13

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θlnS2a ~ N(ln(2), 0.5)

Eq. 14

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In this work we decided to use a weekly informative priors that do not place too much

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probability in any particular interval (and hence favor those values). The θlogkw was assumed to be

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2 ± 5, thus without any data we think that the typical analyte will have logkw,i in a range from -8 to

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12 (± 2 STD around the mean), similarly log km,i and log ka,i were assumed to be in a range from

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(-10 to 10). In the case of the θlnS2m and θlnS2a parameters, the priors' means were based on the

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literature data1, 32,33 with coefficient of variation of 50%, thus S2m,i and S2a,i were assumed to be in

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a range from 0.09 to 0.46 for MeOH and from 0.89 to 4.4 for ACN. Please note that these priors

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can be easily changed to reflect some additional knowledge.

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Further, we decomposed our prior on covariance-matrix into a scale (ω) and a correlation matrix

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(ρ) according to the formula:

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Ω = diag(ω)ρdiag(ω)

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where ω and ρ were given the following priors:

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ωlog kw, ωlog km, ωlog ka, ωlnS2m, ωlnS2a ~ N+ (0,5)

Eq. 16

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ρ ~ LKJ(1) (5x5 matrix)

Eq. 17

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where N+ denotes the half-normal distribution and LKJ denotes the Lewandowski, Kurowicka, and

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Joe distribution34. In this case the LKJ(1) ensures that density is uniform over correlation matrices

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of order 5. Prior for standard deviation for residuals and for the degree of freedom of the MST

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distribution equals:

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σ ~ N+(0, 1)

Eq. 18

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 ~ gamma(2, 0.1)

Eq. 19

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thus favoring normal distribution. The use of student t distribution ensures robustness. It was

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required as there are analytes that differ considerably from typical ones.

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3.3 Model with no pooling

Eq. 15

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By fixing all omegas to a large value, a no pooling approach is obtained. It is equivalent to

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the assumption that there is no information shared between different analytes, thus all analytes-

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specific parameters are essentially estimated based on the analyte-specific data. In this work the

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following values were assumed: ωlog kw, ωlog km, ωlog ka, ωlnS2m, ωlnS2a = 10, ρ is identity matrix of

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size 5 and  equals 20, with the rest of the code being similar as in the previous section.

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3.4 Model with partial pooling and a regression model between analyte-specific parameters and

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analyte-specific properties

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The model with partial pooling can be further extended by adding predictors (descriptors)

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explaining part of the inter-analyte variability. As an example the relationship between log kw,i, log

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ka,i, log km,i and lipophilicity (MLOGPi) or molecular mass (MMOLi) can be proposed as follows:

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[ ] ( [ ] (

)

𝑙𝑜𝑔𝑘𝑤,𝑖 𝜃𝑙𝑜𝑔𝑘𝑤 + 𝛽1,𝑙𝑜𝑔𝑘𝑤·(𝑀𝐿𝑂𝐺𝑃𝑖 ― 2.34) 𝑙𝑜𝑔𝑘𝑚,𝑖 𝜃𝑙𝑜𝑔𝑘𝑚 + 𝛽1,𝑙𝑜𝑔𝑘𝑚·(𝑀𝐿𝑂𝐺𝑃𝑖 ― 2.34) 𝑙𝑜𝑔𝑘𝑎,𝑖 ~𝑀𝑆𝑇 , 𝜃𝑙𝑜𝑔𝑘𝑎 + 𝛽1,𝑙𝑜𝑔𝑘𝑎·(𝑀𝐿𝑂𝐺𝑃𝑖 ― 2.34) ,𝛺 𝑙𝑛𝑆2𝑚,𝑖 𝜃𝑙𝑛𝑆2𝑚 𝑙𝑛𝑆2𝑎,𝑖 𝜃𝑙𝑛𝑆2𝑎

Eq. 20

)

Eq. 21

𝑙𝑜𝑔𝑘𝑤,𝑖 𝜃𝑙𝑜𝑔𝑘𝑤 + 𝛽2,𝑙𝑜𝑔𝑘𝑤·(𝑀𝑀𝑂𝐿𝑖 ― 150) 𝑙𝑜𝑔𝑘𝑚,𝑖 𝜃𝑙𝑜𝑔𝑘𝑚 + 𝛽2,𝑙𝑜𝑔𝑘𝑚·(𝑀𝑀𝑂𝐿𝑖 ― 150) 𝑙𝑜𝑔𝑘𝑎,𝑖 ~𝑀𝑆𝑇 , 𝜃𝑙𝑜𝑔𝑘𝑎 + 𝛽2,𝑙𝑜𝑔𝑘𝑎·(𝑀𝑀𝑂𝐿𝑖 ― 150) ,𝛺 𝑙𝑛𝑆2𝑚,𝑖 𝜃𝑙𝑛𝑆2𝑚 𝑙𝑛𝑆2𝑎,𝑖 𝜃𝑙𝑛𝑆2𝑎

234

Such a relationship is consistent with the expected similarity between log k and MLOGP and

235

between log k and molecular mass as the latter is correlated with log P. In this case the following

236

priors were used β1~N(1.00, 0.50) and β2~N(0.02, 0.01) thus assuming that the relationship

237

between MLOGP and log kw, log km and log ka is linear with a slope close to one, and assuming a

238

linear relationship between molecule mass and log kw, log km and log ka with a slope and standard

239

deviation being 50 time smaller (where 50 is a standard deviation of the molecular masses of

240

the analytes).

241

4. Results and discussion

242

In this work we presented a series of multilevel models obtained during the analysis of

243

isocratic data obtained for 58 compounds in MeOH and ACN. The proposed models provide a

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unified descriptions of the whole dataset. It is in contrary to “classical” methods of analyzing

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chromatographic data, which tend to ignore the hierarchical structure of the data, and perform the

246

analysis at the analyte-level only.

247

Figure 1 and Figure 2 show the individual predictions (prediction corresponding to the

248

future observations on the same analyte) and typical predictions (prediction corresponding to the

249

future observations of a new analyte) for 5 representative compounds selected based on the

250

accuracy of the fit (from the worst to the best based on the root mean square error of the Pooled-

251

log P model), respectively. The individual fits are satisfactory for all the considered models. They

252

are also much better than for the original model that assumed Snyder-Soczewinski equation (data

253

not shown). The similarity of models is also confirmed by the WAIC, LPDCV (all data) and

254

RMSECV (all data) measures, which are essentially identical (Table 1). It means, that given all the

255

observations we can predict analyte retention equally well using any of the presented models. This

256

is not true when trying to predict retention factor for an analyte for which no experimental data is

257

available. Such a typical predictions are presented in Figure 2. The typical predictions show much

258

higher uncertainty than individual predictions, as there is less information about the retention factor

259

for an analyte without any measurements. In this case only the information from other analytes and

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the predictors, such as log P or molecular mass, can be taken into account. In our analysis the

261

predictive performance of the tested models expressed as LPDCV was -232.3 for Pooled-log P, -

262

1436.7 for Pooled-Mmol, -1775.1 for Pooled and finally -4809.6 for the Unpooled model. In the

263

case of an analyte with no measurements, the information about log P leads to more accurate

264

predictions than molecular mass.

265

The goodness of fit plots are presented in Figure 3. These plots shows the relationship

266

between the observations and model predictions (typical and individual) and allow to assess the

267

calibration accuracy and sharpness of predictions35. For individual predictions, both the accuracy

268

(whether the points are close to the line of unity for the whole range of measurements) and

269

sharpness (the spread of the points around the line of identity) are excellent for all the tested models.

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The situation is different for the typical predictions. The accuracy and sharpness is reasonable for

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the Pooled model with predictors (log P reduces uncertainty more than the molecular mass). Please

272

note that the calibration is problematic for the Unpooled and Pooled models, which means that

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those models should be avoided for predictions when there is no information on analyte properties

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available.

275

Supporting Table S1 presents a summary of the marginal posterior distributions for model

276

parameters. These parameters summarize all the important features of the data and can be used by

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others to predict retention factors of new analytes (for a similar column and analytes that were used

278

to develop the model).

279

The mean normality parameter () equals 2.60 and 2.90, depending on the model. Low

280

values of normality parameter indicates that the studied MST distribution has heavy-tails; thus,

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there are analytes that are considerably different from the typical ones. These analytes have unusual

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retention time profile. The 4-aminophenol is an example of such a compound, as it has higher

283

retention in ACN than in MeOH, for the whole range of organic modifier contents (Figure 1).

284

Log P value of a typical analyte in our dataset is 2.34. For such an analyte the estimated log

285

k value equals 3.20 for neat water (log kw), -0.71 for neat MeOH (log km) and -1.00 for neat ACN

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(log ka). Calculated curvature coefficients (S2) equals 0.59 and 1.40, for MeOH and ACN,

287

respectively. These numbers are close to the literature values1,32,33. Also, strong correlation (0.74-

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0.76) between S2 parameters for MeOH and ACN (ρlnS2M, lnS2A) is observed. Mean β1,logkw in the

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Pooled-log P model is close to one (1.30). Mean β1,logkm and β1,logka are much smaller (0.29 and

290

0.21, respectively); however, the trend with log P is evident. Similar situation can be observed for

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β2 parameter - mean β2,logkw (0.029) in the Pooled-Mmol model is close to the prior value (0.02)

292

and β2 for MeOH and ACN are much smaller (0.0058 and 0.0043, respectively), which is a

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consequence of a correlation between log P and molecular mass.

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Correlations between log k parameters corresponding to single-component mobile phases

295

(water, MeOH and ACN) are evident, in particular for the Pooled model (ρlogkm, logka = 0.84, ρlogkm,

296

logkw

297

persist even after including common predictors (0.76, 0.71, 0.74, and 0.53, 0.24, 0.24,

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respectively). If there is a strong correlation between some model parameters, then the information

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on one parameter can give an information about the likely value of the other parameter, e.g.

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correlation between log ka and log km, indicates that knowing retention times of an analyte in water-

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MeOH system gives the analyst information on its retention in the water-ACN system. Thus,

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understanding the correlation can help to make more reliable predictions.

= 0.78, ρlogka, logkw = 0.79). For the Pooled-log P and Pooled-Mmol models this correlation

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Supporting Figure S2 presents the individual (analyte-specific) parameters for 5

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representative analytes as obtained by the four considered models. The regularization imposed by

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the multilevel model is immediately visible by comparing the uncertainty of parameters obtained

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using the Unpooled and Pooled models. In the case of the pooled approach the uncertainty is

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reduced and the individual values are “shrunk” toward the typical values. It is especially visible for

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parameters that are difficult to estimate (such as ln S2m,i and ln S2a,i).

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Multilevel models proposed in this work are a natural framework for understanding

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chromatographic data. They are also useful in making predictions of retention times in the case of

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limited chromatographic data; e.g., for situations that are usually of interest to analyst. In this work

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we illustrated this concept by predicting the retention times in a situation of limited access to the

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chromatographic data. Specifically the access to the none, single MeOH (1M), single ACN (1A),

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single MeOH and single ACN (1M & 1A), all MeOH (AllM) and all ACN (AllA) measurements

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were considered. Figure 4 illustrates the agreement between predictions (using cross-validation)

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and observations for all the models and 6 considered scenarios. It can be used to assess accuracy

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and sharpness, similarly, as was done previously. The predictive performance is summarized in

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Table 1. The predictions along with the uncertainty are shown in Supporting Figures S-3 and S-4

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for 4-aminophenol (the worst fit, with unusual retention time profile) and xanthene (the best fit),

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respectively.

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It is clear that more experimental data leads to more accurate predictions. Interestingly, the

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pooled models are reasonably well calibrated whenever there is at least one measurement available

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for predictions. Still the sharpness of predictions is slightly better once predictors (molecular mass

324

or log P) are included into the model. Thanks to the application of the knowledge on the whole

325

population of analytes (pooling), addition of single experimental point for just one mobile phase

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(MeOH or ACN-containing mobile phases) results in the significant reduction of uncertainty

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around predictions, for both eluents. Such an effect is not observed for the Unpooled model. In this

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case, access to the experimental data in one of the organic modifier improves the predictions only

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for that specific eluent, without influencing the other. The degree of uncertainty reduction can be

330

assessed investigating LPDCV and RMSECV measures in Table 1 and by the visual inspection of

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Supporting Figures S-3 and S-4.

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The LPDCV can be directly used to compare the models (with the higher values denoting

333

higher predictive performance). In general, when comparing all the predictive accuracy measures

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(WAIC, LPDCV, RMSECV), goodness-of-fit-plots and cross-validation plots, the Pooled-log P

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and Pooled-Mmol model leads to useful, well-calibrated, predictions in situations where limited

336

data is available for predictions. Obviously, the worst predictive accuracy has the Unpooled model,

337

unless large number of analytes-specific measurements are available.

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5. Conclusions

339

In this work we proposed and compared several multilevel chromatographic retention

340

models. Such models allow to efficiently share information between analytes and organic modifiers

341

that can be used to predict retention and associated uncertainty for new analytes or analytes with

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only few measurements available. In particular, they can be helpful to solve many practical

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analytical problems, such as predicting retention times in ACN-containing mobile phases given no,

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one or several measurements in MeOH-containing mobile phases.

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The Bayesian multilevel modeling is mathematically sophisticated; thus, it has been rarely

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applied in the field of analytical chemistry. Nevertheless, the recent advances in providing the state-

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of-the-art platforms for statistical modeling and high-performance statistical computation (Stan's

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probabilistic programming language) makes those models attractive in solving everyday separation

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prediction problems encountered by chromatography practitioners.

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6. References

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(1) Nikitas, P.; Pappa-Louisi A., J. Chromatogr. A 2009, 1216, 1737-1755.

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(2) Gritti, F.; Guiochon, G., Anal. Chem. 2005, 77, 4257–4272.

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(3) Kazakevich, Y.V.; LoBrutto, R.; Chan, F.; Patel, T., J. Chromatogr. A 2001, 913, 75-87.

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(4) DryLab®, Molnár-Institute for applied chromatography, Berlin, Germany, molnar-

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institute.com.

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(5) Leweke, S.; von Lieres, E., Comput. Chem. Eng. 2018, 113, 274-294.

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(6) Wen,Y.; Talebi, M.; Amos, R.I.J.; Szucs, R; Dolan, J.W.; Pohl C.A.; Haddad P.R.; J

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Chromatogr A. 2018, 1541, 1-11.

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(7) Vander Heyden, Y.; Perrinam C.; Massarta, D.L. Handbook of Analytical Separations,

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2000, 1, 163-212.

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(8) Zahnd, W.E.; McLafferty, S.L., Ann Epidemiol. 2017, 27, 739-748.

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(9) Hastings, R.H.; Glaser, D., Anesth. Analg. 2011, 113, 877-887.

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(10) Schreiber, J.B.; Griffin, B.W., J. Educ. Res. 2004, 98, 24-33.

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(11) Wiczling, P.; Kaliszan, R., Anal. Chem. 2016, 88, 997-1002.

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(12) Wiczling, P.; Kubik, Ł.; Kaliszan, R., Anal. Chem. 2015, 87, 7241-7249.

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(13) Barcaru, A.; Mol, H.G.J.; Tienstra, M.; Vivó-Truyols, G., Anal. Chim. Acta 2017, 983, 76-90.

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(14) Wiczling, P., Anal. Bioanal. Chem. 2018, 410, 3905-3915.

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(15) Al-Haj, M.A.; Kaliszan, R.; Nasal A., Anal. Chem. 1999, 71, 2976-2985.

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(16) HyperChem™, Hypercube Inc., Waterloo, ON, Canada, 1999.

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(17) O'Boyle, N.; Banck, M.; James, C.A.; Morley, C.; Vandermeerschm, T.; Hutchison, G.R., J.

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Cheminform. 2011, 3, 33.

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(18) Dassault Systèmes BIOVIA, Discovery Studio Visualizer, Release 16.1, San Diego: Dassault

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Systèmes, 2015.

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(19) Hahn, M., J. Med. Chem. 1995, 38, 2080-2090.

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(20) GaussView, Version 3.09, Roy Dennington, Todd Keith and John Millam, Semichem Inc.,

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Shawnee Mission, KS, 2009.

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(21) Gaussian 09, Revision A.02, M. J. Frisch et al., Gaussian, Inc., Wallingford, CT, 2009.

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(22) Kodesrl, Dragon (software for molecular descriptor calculation) version 7.0.6, 2016,

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https://chm.kode-solutions.net.

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(23) Carpenter, B.; Gelman, A.; Hoffman, M.D.; Lee, D.; Goodrich, B.; Betancourt, M.; Brubaker,

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M.; Guo, J.; Li, P.; Riddell A., J. Stat. Softw. 2017, 76. 1-32.

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(24) Stan Development Team. 2017. CmdStan: the command-line interface to Stan, Version 2.16.0,

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http://mc-stan.org.

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(25) MATLAB® and Statistics Toolbox Release R2017b, The MathWorks®, Inc., Natick,

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Massachusetts, United States.

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(26) Stan Development Team. 2017. MatlabStan: the MATLAB interface to Stan, http://mc-

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stan.org.

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(27) https://github.com/stan-dev/stan/wiki/Complex-ODE-Based-Models.

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(28)

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ode.html.

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(29) Gelman, A.; Carlin, J.B.; Stern, H.S.; Rubin, D.B., Bayesian data analysis, 2nd ed.; Chapman

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& Hall/CRC Texts in Statistical Science: Boca Raton, 2004.

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(30) Vehtari, A.; Gelman, A.; Gabry, J., Stat Comput. 2017, 27, 1413-1432.

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(31) Neue, U.D.; Phoebe, C.H.; Tran, K.; Cheng, Y.F.; Lu, Z., J. Chromatogr. A 2001, 925, 49-67.

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(32) Pappa-Louisi A.; Nikitas, P.; Balkatzopoulou, P.; Malliakas, C., J. Chromatogr. A 2004, 1033,

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29-41.

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(33) Snyder, L.R.; Kirkland, J.J.; Dolan, J.W., Introduction to modern liquid chromatography, 3rd

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ed.; Wiley-Blackwell: Oxford, 2010.

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(34) Lewandowski, D.; Kurowicka, D.; Joe H., J. Multivar. Anal. 2009, 100, 1989-2001.

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(35) Gneiting, T.; Balabdaoui, F.; Raftery, A.E., J. Royal Stat. Soc., Series B 2007, 69, 243-268.

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7. Acknowledgements

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This Project was supported by the National Science Centre, Poland (grant 2015/18/E/ST4/00449)

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and from the funds of the Polish Ministry of Science and Higher Education, granted for the

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development of the young scientists (participants of the doctoral studies) - no. 01-0224/08/529.

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Part of the calculations were carried out at the Academic Computer Centre in Gdańsk.

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8. Conflict of Interest Disclosure

http://mc-stan.org/events/stancon2017-notebooks/stancon2017-margossian-gillespie-

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Analytical Chemistry

The authors declare no competing financial interest.

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408

Tables

409

Table 1. The summary of predictive performance measures used to compare the tested models.

410

The predictive performance (log pointwise predictive density (LPDCV) and root mean square error

411

(RMSECV)) was assessed based on 10-fold cross-validation for 4 tested models and 6 prediction

412

scenarios (based on no measurements (None), single MeOH measurement (1M), single ACN

413

measurement (1A), single MeOH and single ACN measurement (1M & 1A), all ACN

414

measurements (AllA) and all MeOH measurements (AllM)). WAIC is an approximation of leave-

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one-out measurement cross validation. Available

Unpooled

Pooled

Pooled-log P

Pooled-Mmol

-5823.7 0

-5814.2 -9.5

-5822.7 -1.0

data WAIC of the models All Data: WAIC ΔWAIC

-5832.5 8.7

LPDCV (LPDCV for MeOH data/LPDCV for ACN data) after 10-fold cross validation -4809.6 -1775.1 -232.3 -1436.7 (-3073.5/-1736.2) (-1161.4/-613.7) (-198.5/-33.8) (-955.4/-481.3) -3168.0 928.4 931.5 1027.3 1M (-1509.5/-1658.5) (753.2/175.2) (751.1/180.4) (828.1/199.2) -3551.7 773.4 893.6 948.5 1A (-3015.3/-536.4) (228.7/544.7) (308.8/584.8) (222.3/726.1) -1773.7 1373.4 1482.5 1636.7 1M & 1A (-1327.4/-446.3) (845.8/527.6) (855.6/626.9) (914.3/722.3) 429.4 2222.7 2249.0 2236.0 AllM (1962.1/-1532.7) (1948.3/274.5) (1946.1/302.9) (1949.3/286.7) -1692.8 1478.8 1540.0 1503.0 AllA (-2902.3/1209.6) (262.5/1216.2) (326.9/1213.1) (288.8/1214.1) 3171.7 3164.5 3159.2 3163.4 All Data: (1962.1/1209.6) (1948.3/1216.2) (1946.1/1213.1) (1949.3/1214.1) RMSECV (RMSECV for MeOH data/RMSECV for ACN data) after 10-fold cross validation

None

None

0.81 (0.85/0.72)

0.78 (0.82/0.73)

0.30 (0.33/0.26)

0.62 (0.64/0.59)

1M

0.48 (0.36/0.63)

0.18 (0.19/0.18)

0.18 (0.18/0.17)

0.18 (0.17/0.19)

1A

0.98 (1.2/0.34)

0.18 (0.22/0.094)

0.18 (0.21/0.096)

0.18 (0.21/0.091)

1M & 1A

0.36 (0.42/0.20)

0.16 (0.19/0.087)

0.15 (0.17/0.091)

0.15 (0.17/0.086)

AllM

0.37 (0.033/0.62)

0.12 (0.034/0.19)

0.11 (0.034/0.17)

0.11 (0.033/0.18)

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AllA

0.79 (0.99/0.024)

0.20 (0.25/0.024)

0.20 (0.25/0.024)

0.20 (0.25/0.024)

All Data:

0.03 (0.033/0.024)

0.03 (0.033/0.024)

0.03 (0.033/0.024)

0.03 (0.033/0.024)

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Figures

417

Figure 1. Predicted (posterior median (line) and 95% credible intervals (shaded area)) and

418

observed retention factors (dots) for 5 representative analytes. Predictions correspond to the future

419

observations on the same analyte, i.e. posterior predictions conditioned on the observed data from

420

the same analyte. Black color corresponds to MeOH whereas red color corresponds to ACN.

421

Figure 2. Predicted (posterior median (line) and 95% credible intervals (shaded area)) and

422

observed retention factors (dots) for 5 representative analytes. Prediction corresponds to the future

423

observations of a new analyte, i.e. posterior predictive distributions. Black color corresponds to

424

MeOH whereas red color corresponds to ACN. For the Unpooled model the median is not smooth

425

due to large posterior variability.

426

Figure 3. Goodness-of-fit-plots of the four considered models. The observed versus the mean

427

typical predicted retention factors (the a posteriori mean of a predictive distributions corresponding

428

to the future observations of a new analyte) and the observed versus the mean individual predicted

429

retention times (the a posteriori mean of a predictive distributions conditioned on the observed

430

data from the same analyte). The black symbols denote MeOH and the red symbols denote ACN.

431

Figure 4. Goodness-of-fit-plots of the four considered models after 10-fold cross-validation. The

432

graph shows the observed versus the mean predicted retention factors (the a posteriori mean of a

433

predictive distributions conditioned on the part of the observed data (specifically none, single

434

MeOH (1M), single ACN (1A), single MeOH and single ACN (1M & 1A), All MeOH (AllM) and

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all ACN (AllA)) from the same analyte. The red symbols denote predictions for ACN and black

436

symbols denote predictions for MeOH.

437 438

For TOC only:

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Analytical Chemistry

Figure 1 Predicted (posterior median (line) and 95% credible intervals (shaded area)) and observed retention factors (dots) for 5 representative analytes. Predictions correspond to the future observations on the same analyte, i.e. posterior predictions conditioned on the observed data from the same analyte. Black color corresponds to MeOH whereas red color corresponds to ACN. 165x180mm (300 x 300 DPI)

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Figure 2. Predicted (posterior median (line) and 95% credible intervals (shaded area)) and observed retention factors (dots) for 5 representative analytes. Prediction corresponds to the future observations of a new analyte, i.e. posterior predictive distributions. Black color corresponds to MeOH whereas red color corresponds to ACN. For the Unpooled model the median is not smooth due to large posterior variability. 165x180mm (300 x 300 DPI)

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Figure 3. Goodness-of-fit-plots of the four considered models. The observed versus the mean typical predicted retention factors (the a posteriori mean of a predictive distributions corresponding to the future observations of a new analyte) and the observed versus the mean individual predicted retention times (the a posteriori mean of a predictive distributions conditioned on the observed data from the same analyte). The black symbols denote MeOH and the red symbols denote ACN. 165x180mm (300 x 300 DPI)

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Figure 4. Goodness-of-fit-plots of the four considered models after 10-fold cross-validation. The graph shows the observed versus the mean predicted retention factors (the a posteriori mean of a predictive distributions conditioned on the part of the observed data (specifically none, single MeOH (1M), single ACN (1A), single MeOH and single ACN (1M & 1A), All MeOH (AllM) and all ACN (AllA)) from the same analyte. The red symbols denote predictions for ACN and black symbols denote predictions for MeOH. 165x180mm (300 x 300 DPI)

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