posted on 2018-09-18, 00:00authored byG. McConnell, S. Mabbott, A. L. Kanibolotsky, P. J. Skabara, D. Graham, G. A. Burley, N. Laurand
Organic
semiconductor lasers are a sensitive biosensing platform
that respond to specific biomolecule binding events. So far, such
biosensors have utilized protein-based interactions for surface functionalization
but a nucleic acid–based strategy would considerably widen
their utility as a general biodiagnostic platform. This manuscript
reports two important advances for DNA-based sensing using an organic
semiconductor (OS) distributed feedback (DFB) laser. First, the immobilization
of alkyne-tagged 12/18-mer oligodeoxyribonucleotide (ODN) probes by
Cu-catalyzed azide alkyne cycloaddition (CuAAC) or “click-chemistry”
onto an 80 nm thick OS laser film modified with an azide-presenting
polyelectrolyte monolayer is presented. Second, sequence-selective
binding to these immobilized probes with complementary ODN-functionalized
silver nanoparticles, is detected. As binding occurs, the nanoparticles
increase the optical losses of the laser mode through plasmonic scattering
and absorption, and this causes a rise in the threshold pump energy
required for laser action that is proportional to the analyte concentration.
By monitoring this threshold, detection of the complementary ODN target
down to 11.5 pM is achieved. This complementary binding on the laser
surface is independently confirmed through surface-enhanced Raman
spectroscopy (SERS).