Department of Chemistry and Biochemistry, University of California Santa Cruz, Santa Cruz, California 95064, USA.
Inorg Chem. 2009 Jul 20;48(14):6904-17. doi: 10.1021/ic900899j.
Three ruthenium nitrosyl-dye conjugates, namely, [((OMe)(2)bQb)Ru(NO)(Resf)] (RuNO-Resf), [((OMe)(2)bQb)Ru(NO)(Thnl)] (RuNO-Thnl), and [((OMe)(2)bQb)Ru(NO)(Seln)] (RuNO-Seln) have been synthesized using the tetradentate N4 dicarboxamido ligand H(2)(OMe)(2)bQb. Each nitrosyl of this series is conjugated to a phenoxazine-type heterotricyclic chromophore which has been systematically varied in a central position to test the effects of "heavy-atom" substitution (O = Resorufin; S = Thionol; Se = Selenophore) in photosensitization. The structure of the chloride-bound precursor {Ru-NO}(6) nitrosyl [((OMe)(2)bQb)Ru(NO)(Cl)] (RuNO-Cl) and three nitrosyl-dye conjugates, namely, RuNO-Resf, RuNO-Thnl and RuNO-Seln, have been determined by X-ray crystallography. All three nitrosyl-dye conjugates exhibit sharp (1)H NMR spectra (S = 0 ground state) and nu(NO) stretches in the IR spectrum in the region 1825-1855 cm(-1), typical of {Ru-NO}(6) nitrosyls. The presence of a heavy atom in the bound dye gives rise to a systematic red-shift in the electronic absorption spectrum, shifting from RuNO-Resf (lambda(max) = 500 nm) to RuNO-Thnl (lambda(max) = 530 nm) to RuNO-Seln (lambda(max) = 535 nm). Results of careful measurements with monochromatic light sources indicate that heavy-atom substitution in the coordinated dye makes the resulting nitrosyl-dye conjugates more susceptible to light of longer wavelength (lower energy). Density functional theory (DFT) calculations on RuNO-Cl, RuNO-Resf, RuNO-Thnl, and RuNO-Seln have been performed to gain insight into the electronic structure of the {dye-Ru-NO} frame and the nature of transition(s) that sensitizes these conjugates to lights of longer wavelengths and promote NO photolability. Results of this study provide an explanation for the sensitization observed in our strategy of direct attachment of dye molecules to {Ru-NO}(6) nitrosyls. This strategy could lead to eventual isolation of designed metal nitrosyls that are sensitive to red- or near-infrared light and hence potential photodynamic therapy (PDT) agents for treatment of malignancies with high doses of NO.
三种钌亚硝酰-染料缀合物,即 [((OMe)(2)bQb)Ru(NO)(Resf)] (RuNO-Resf)、[((OMe)(2)bQb)Ru(NO)(Thnl)] (RuNO-Thnl) 和 [((OMe)(2)bQb)Ru(NO)(Seln)] (RuNO-Seln),已使用四齿 N4 二羧酰胺配体 H(2)(OMe)(2)bQb 合成。该系列中的每个亚硝酰均与苯并噁嗪型杂三环生色团共轭,该生色团在中央位置得到了系统的变化,以测试“重原子”取代(O = Resorufin;S = Thionol;Se = Selenophore)在光致敏化中的作用。结合态氯化物 {Ru-NO}(6) 亚硝酰 [((OMe)(2)bQb)Ru(NO)(Cl)] (RuNO-Cl) 和三种亚硝酰-染料缀合物,即 RuNO-Resf、RuNO-Thnl 和 RuNO-Seln 的结构已通过 X 射线晶体学确定。所有三种亚硝酰-染料缀合物均表现出尖锐的 (1)H NMR 光谱(S = 0 基态)和 IR 光谱中在 1825-1855 cm(-1) 区域的 nu(NO)伸展,这是典型的 {Ru-NO}(6) 亚硝酰。结合染料中重原子的存在会导致电子吸收光谱的系统红移,从 RuNO-Resf(lambda(max) = 500nm)到 RuNO-Thnl(lambda(max) = 530nm)再到 RuNO-Seln(lambda(max) = 535nm)。用单色光源进行的仔细测量结果表明,配位染料中的重原子取代使所得的亚硝酰-染料缀合物更容易受到长波长(低能量)光的影响。对 RuNO-Cl、RuNO-Resf、RuNO-Thnl 和 RuNO-Seln 进行了密度泛函理论 (DFT) 计算,以深入了解 [染料-Ru-NO] 框架的电子结构以及敏化这些缀合物的光的性质。更长波长的跃迁(s)并促进 NO 光解。该研究的结果为我们将染料分子直接附着到 {Ru-NO}(6) 亚硝酰的策略中观察到的敏化提供了解释。这种策略可能导致最终分离出对红光或近红外光敏感的设计金属亚硝酰,从而为使用高剂量 NO 治疗恶性肿瘤的光动力疗法 (PDT) 提供潜在的光敏剂。
