posted on 2021-10-07, 18:34authored byDon M. Mayder, Christopher M. Tonge, Giang D. Nguyen, Michael V. Tran, Gary Tom, Ghinwa H. Darwish, Rupsa Gupta, Kelsi Lix, Saeid Kamal, W. Russ Algar, Sarah A. Burke, Zachary M. Hudson
Semiconducting
polymer dots (Pdots) have emerged as versatile probes
for bioanalysis and imaging at the single-particle level. Despite
their utility in multiplexed analysis, deep blue Pdots remain rare
due to their need for high-energy excitation and sensitivity to photobleaching.
Here, we describe the design of deep blue fluorophores using structural
constraints to improve resistance to photobleaching, two-photon absorption
cross sections, and fluorescence quantum yields using the hexamethylazatriangulene
motif. Scanning tunneling microscopy was used to characterize the
electronic structure of these chromophores on the atomic scale as
well as their intrinsic stability. The most promising fluorophore
was functionalized with a polymerizable acrylate handle and used to
give deep-blue fluorescent acrylic polymers with Mn > 18 kDa and Đ < 1.2. Nanoprecipitation
with amphiphilic polystyrene-graft-(carboxylate-terminated
poly(ethylene glycol)) gave water-soluble Pdots with blue fluorescence,
quantum yields of 0.81, and molar absorption coefficients of (4 ±
2) × 108 M–1 cm–1. This high brightness facilitated single-particle visualization
with dramatically improved signal-to-noise ratio and photobleaching
resistance versus an unencapsulated dye. The Pdots were then conjugated
with antibodies for immunolabeling of SK-BR3 human breast cancer cells,
which were imaged using deep blue fluorescence in both one- and two-photon
excitation modes.