Study of the Variation of the Electronic Distribution
and Motional Dynamics of Two Independent Molecules of an Asymmetric
Unit of Atorvastatin Calcium by Solid-State NMR Measurements
Significant changes
in the spin-lattice time and chemical shift
anisotropy (CSA) parameters are observed in two independent molecules
of an asymmetric unit of atorvastatin calcium (ATC-I) (which is referred
to as “a”- and “b”-type molecules by following
Wang et al.). The longitudinal magnetization decay curve is fitted
by two exponentialsone with longer relaxation time and another
with shorter relaxation time for most of the carbon nuclei sites.
The local correlation time also varies significantly. This is the
experimental evidence of the coexistence of two different kinds of
motional degrees of freedom within ATC-I molecule. The solubility
and bioavailability of the drug molecule are enhanced due to the existence
of two different kinds of dynamics. Hence, the macroscopic properties
like solubility and bioavailability of a drug molecule are highly
correlated with its microscopic properties. The motional degrees of
freedom of “a”- and “b”-type molecules
are also varied remarkably at certain carbon nuclei sites. This is
the first time the change in the molecular dynamics of two independent
molecules of an asymmetric unit of atorvastatin calcium is quantified
using solid-state NMR methodology. These types of studies, in which
the chemical shift anisotropy (CSA) parameters and spin-lattice relaxation
time provide information about the change in electronic distribution
and the spin dynamics at the various crystallographic location of
the drug molecule, will enrich the field “NMR crystallography”.
It will also help us to understand the electronic distribution around
a nucleus and the nuclear spin dynamics at various parts of the molecule,
which is essential to develop the strategies for the administration
of the drug.