Carbon disulfide, a potentially therapeutic small molecule, is generated via oxidative cleavage of 1,1-dithiooxalate (DTO) photosensitized by CdSe quantum dots (QDs). Irradiation of DTO−QD conjugates leads to λ irr independent photooxidation with a quantum yield of ∼4% in aerated pH 9 buffer solution that drops sharply in deaerated solution. Excess DTO is similarly decomposed, indicating labile exchange at the QD surfaces and a photocatalytic cycle. Analogous photoreaction occurs with the O-tert-butyl ester t BuDTO in nonaqueous media. We propose that oxidation is initiated by hole transfer from photoexcited QD to surface DTO and that these substrates are a promising class of photocleavable ligands for modifying QD surface coordination.S emiconductor quantum dots (QDs) exhibit size and composition dependent optical properties, strong absorption cross sections, high photoluminescence (PL) quantum yields, and customizable solubility through surface ligand exchange. 1 These properties position QDs as attractive sensitizers for photodynamic therapy, 2 photoactivated drug delivery, 3 solar energy conversion, 4 and photocatalysis. 5 Here we describe the photocatalytic cleavage of 1,1-dithiooxalate (DTO) to CS 2 and CO 2 mediated by CdSe QDs. This process serves to "uncage" carbon disulfide (CS 2 ), a potentially therapeutic agent. Similar reactions are observed with the DTO ester t BuDTO, and light activated cleavage of such ligands suggests strategies for the controlled modification of quantum dot surfaces.Fragmentary evidence points toward possible therapeutic roles for carbon disulfide. 6 For example, CS 2 may react with biological amines to form dithiocarbamates, known inhibitors 7 of nuclear factor κB (NF-κB), 8 a crucial mediator in inflammation induced tumor growth and progression. 9 Indeed, dithiocarbamates have been proposed as anticancer agents. 10 Physiological responses to CS 2 or dithiocarbamates include cell growth, apoptosis, and neurotransmission, which are also functions of the small molecule bioregulators NO, CO, and H 2 S. 11 Like each of these, CS 2 is considered toxic at higher concentrations, although epidemiological data are contradictory. 12 Thus, the benefit of balancing the therapeutic and toxic effects of CS 2 make the prospect of controlled, targeted delivery an attractive goal.In these contexts, we are probing DTO−QD conjugates as photochemical CS 2 precursors. These were readily prepared by exchanging DTO dianions for the myristate ligands (n-C 13 H 27 CO 2 − ) originally terminating the QD surface (see Supporting Information (SI) for procedures). Ligand exchange is evidenced by the solubility shift from organic to aqueous media as dianionic DTO replaces the hydrophobic myristate. Purified conjugates show a very strong UV absorption band (∼335 nm) nearly the same as free DTO (λ max ∼335 nm, ε max = 1.5 × 10 4 M −1 cm −1 in aq. solution) and a QD exciton band red-shifted by as much as 40 nm (Figure 1, SI Table S-1).Analogous red shifts in exciton absorptions have been seen when...
