Eb. Ledesma et Mj. Wornat, QSRR prediction of chromatographic retention of ethynyl-substituted PAH from semiempirically computed solute descriptors, ANALYT CHEM, 72(21), 2000, pp. 5437-5443
Retention prediction of 12 ethynyl-substituted polycyclic aromatic hydrocar
bons (PAH) and their six unsubstituted parent compounds has been elucidated
by the application of quantitative structure-retention relationship (QSRR)
analysis. Retention data of the PAH were obtained from reversed-phase high
-pressure liquid chromatography (HPLC) utilizing an octadecylsilica station
ary phase operated under linear-gradient elution (60:40 water/acetonitrile
to pure acetonitrile in 40 min). Six solute descriptors (moment of inertia,
total energy, polarizability, ionization potential, dipole moment, subpola
rity), computed from the optimized semiempirical AM1, MNDO, and PM3 solute
geometries, were examined. Results from one-parameter QSRR analysis showed
that retention of solutes was best predicted with solute polarizability as
the parameter, computed from the AM1- (r = 0.969), MNDO-(r = 0.970), or PM3
(r = 0.967)-optimized solute geometries, From two-parameter QSRR analysis
involving a size-specific parameter accompanied by a polarity parameter, it
was found that solute retention was best reproduced by using solute polari
zability and subpolarity as the parameters calculated from the AM1- (r = 0.
983), MNDO- (r = 0.983), or PM3 (r = 0.984)-optimized solute geometries, On
the basis of the results from both one-parameter and two-parameter regress
ion analysis, the two-parameter QSRR equation with polarizability and subpo
larity as parameters was found to be the best relation in relating solute m
olecular structure to retention under the HPLC conditions investigated. The
results obtained in this study are of significance to predicting the ident
ity of unknown product components based solely on parameters derived from s
olute structure.