Harnessing cyanine photooxidation: from slowing photobleaching to near-IR uncaging

Light provides a uniquely powerful stimulus to help visualize and/or perturb biological systems. The use of tissue penetrant near-IR wavelengths enables in vivo applications, however the design of molecules that function in this range remains a substantial challenge. Heptamethine cyanine fluorophores are already important tools for near-IR optical imaging. These molecules are susceptible to photobleaching through a photooxidative cleavage reaction. This review details efforts to define the mechanism of this reaction and two emerging fields closely tied to this process. In the first, efforts that slow photooxidation enable the creation of photobleaching resistant fluorophores. In the second, cyanine photooxidation has recently been employed as the cornerstone of a near-IR uncaging strategy. This review seeks to highlight the utility of mechanistic organic chemistry insights to help tailor cyanine scaffolds for new, and previously intractable, biological applications.