Supramolecular chemistry
in aqueous media is an area with great
fundamental and practical significance. To examine the role of multiple
noncovalent interactions in controlled assembling and binding behavior
in water, the self-association of five water-soluble hexakis(m-phenylene ethynylene) (m-PE) macrocycles,
along with the molecular recognition behavior of the resultant assemblies,
is investigated with UV–vis, fluorescence, CD, and NMR spectroscopy,
mass spectrometry, and computational studies. In contrast to their
different extents of self-aggregation in organic solvents, all five
macrocycles remain aggregated in water at concentrations down to the
micromolar (μM) range. CD spectroscopy reveals that 1-F
6
and 1-H
6
, two macrocycles carrying chiral side chains and capable of
H-bonded self-association, assemble into tubular stacks. The tubular
stacks serve as supramolecular hosts in water, as exemplified by the
interaction of macrocycles 1-H6
and 2-H
6
and guests G1 through G4, each having a rod-like oligo(p-phenylene
ethynylene) (p-PE) segment flanked by two hydrophilic
chains. Fluorescence and 1H NMR spectroscopy revealed the
formation of kinetically stable, discrete assemblies upon mixing 2-H
6
and a guest. The binding stoichiometry,
determined with fluorescence, 1H NMR, and ESI-MS, reveals
that the discrete assemblies are novel pseudorotaxanes, each containing
a pair of identical guest molecules encased by a tubular stack. The
two guest molecules define the number of macrocyclic molecules that
comprise the host, which curbs the “infinite” stack
growth, resulting in a tubular stack with a cylindrical pore tailoring
the length of the p-PE segment of the bound guests.
Each complex is stabilized by the action of multiple noncovalent forces
including aromatic stacking, side-chain H-bonding, and van der Waals
interactions. Thus, the interplay of multiple noncovalent forces aligns
the molecules of macrocycles 1 and 2 into
tubular stacks with cylindrical inner pores that, upon binding rod-like
guests, lead to tight, discrete, and well-ordered tubular assemblies
that are unprecedented in water.