posted on 2015-08-18, 00:00authored byKay M. Brummond, Laura S. Kocsis
ConspectusReaction
discovery plays a vital role in accessing new chemical
entities and materials possessing important function. In this Account, we delineate our reaction discovery program
regarding the [4 + 2] cycloaddition reaction of styrene-ynes. In particular,
we highlight our studies that lead to the realization of the diverging
reaction mechanisms of the intramolecular didehydro-Diels–Alder
(IMDDA) reaction to afford dihydronaphthalene and naphthalene products.
Formation of the former involves an intermolecular hydrogen atom abstraction
and isomerization, whereas the latter is formed via an unexpected
elimination of H2. Forming aromatic compounds by a unimolecular
elimination of H2 offers an environmentally benign alternative
to typical oxidation protocols.We also include in this Account
ongoing work focused on expanding
the scope of this reaction, mainly its application to the preparation
of cyclopenta[b]naphthalenes. Finally, we showcase
the synthetic utility of the IMDDA reaction by preparing novel environmentally
sensitive fluorophores.The choice to follow this path was largely
influenced by the impact
this reaction could have on our understanding of the structure–function
relationships of these molecular sensors by taking advantage of a de novo construction and functionalization of the aromatic
portion of these compounds. We were also inspired by the fact that,
despite the advances that have been made in the construction of small
molecule fluorophores, access to rationally designed fluorescent probes
or sensors possessing varied and tuned photophysical, spectral, and
chemical properties are still needed.To this end, we report
our studies to correlate fluorophore structure
with photophysical property relationships for a series of solvatochromic
PRODAN analogs and viscosity-sensitive cyanoacrylate analogs. The
versatility of this de novo strategy for fluorophore
synthesis was demonstrated by showing that a number of functional
groups could be installed at various locations, including handles
for eventual biomolecule attachment or water-solubilizing groups.
Further, biothiol sensors were designed, and we expect these to be
of general utility for the study of lipid dynamics in cellular membranes
and for the detection of protein-binding interactions, ideal applications
for these relatively hydrophobic fluorophores. Future studies will
be directed toward expanding this chemistry-driven approach to the
rational preparation of fluorophores with enhanced photophysical and
chemical properties for application in biological systems.