Two-Photon Photosensitized Production of Singlet Oxygen

Frederiksen, Peter; Jørgensen, Mikkel; Ogilby, Peter R.

doi:10.1021/ja003468a

Cited by 259 publications

(224 citation statements)

References 21 publications

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“…In the quest of improving NLO properties, attention has been essentially focused on dipolar molecules for several decades. [1][2][3] More recently, quadrupolar systems have been designed and investigated [4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21] and have shown improved properties, in particular with respect to the trade-off between optical transparency and NLO performance. Lately, attention has turned toward multipolar [22][23][24][25][26][27][28][29][30][31][32][33] and branched structures including dendrimers.…”

Section: Introductionmentioning

confidence: 99%

Effects of (Multi)branching of Dipolar Chromophores on Photophysical Properties and Two-Photon Absorption

et al. 2005

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To investigate the effect of branching on linear and nonlinear optical properties, a specific series of chromophores, epitome of (multi)branched dipoles, has been thoroughly explored by a combined theoretical and experimental approach. Excited-state structure calculations based on quantum-chemical techniques (timedependent density functional theory) as well as a Frenkel exciton model nicely complement experimental photoluminescence and one-and two-photon absorption findings and contribute to their interpretation. This allowed us to get a deep insight into the nature of fundamental excited-state dynamics and the nonlinear optical (NLO) response involved. Both experiment and theory reveal that a multidimensional intramolecular charge transfer takes place from the donating moiety to the periphery of the branched molecules upon excitation, while fluorescence stems from an excited state localized on one of the dipolar branches. Branching is also observed to lead to cooperative enhancement of two-photon absorption (TPA) while maintaining high fluorescence quantum yield, thanks to localization of the emitting state. The comparison between results obtained in the Frenkel exciton scheme and ab initio results suggests the coherent coupling between branches as one of the possible mechanisms for the observed enhancement. New strategies for the rational design of NLO molecular assemblies are thus inferred on the basis of the acquired insights.

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Section: Introductionmentioning

confidence: 99%

Effects of (Multi)branching of Dipolar Chromophores on Photophysical Properties and Two-Photon Absorption

et al. 2005

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“…These groups constitute an attractive trigger because UV light induced Wolff rearrangement of DNQ to a 3-indenecarboxylic acid group with hydrophilic properties enhancing water solubility of that compound. Moreover, infrared light can be applied in photodynamic therapy [217][218][219][220] and liposome degradation [221]. Furthermore, mechanopores along the polymer poly(methyl acrylate) backbone (e.g., cyclobutane mechanopores) can be activated in polymers containing a coumarin dimer probe by mechanochemical scisson under pulsed ultrasound conditions (sonochemical) in solid state [222].…”

Section: Non-fluorescent Prodrugs/converted Into Fluorescent Active Dmentioning

confidence: 99%

Fluorescent Dyes Used in Polymer Carriers as Imaging Agents in Anticancer Therapy

Miksa¹

2016

Med chem (Los Angeles)

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This review highlights the role of fluorescent dyes as active "molecular photoswiches" focusing on the application in bioimaging and anticancer therapies in the field of therapeutic delivery. The author describes the development of prodrugs targeted to specific cell types and polymeric nanocarriers (capsules, micelles and silica nanoparticles) used as fluorescent probes which offer advantages in the integration of "smart" features of fluorescent dyes into synthetic materials. The incorporation of biologically responsive components that cleave upon changes in pH or light irradiation is fundamental to the successful design of such carriers with capabilities to load and release therapeutics specifically at a target site.

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“…Near-infrared photon has remarkable advantage, such as low energy, excellent penetration and negligible damage to normal biological tissues. Hence, the utilization of near-IR laser to irradiate two-photon triplet photosensitizers to generate singlet oxygen receives considerable attentions [12][13][14][15][16][17][18]. While unfortunately, near-infrared TPA photodynamic therapy has never reached its full potentials due to the absence of the criteria for the design of photosensitizers with large twophoton absorption cross sections and high singlet oxygen quantum yields.…”

mentioning

confidence: 99%

“…While unfortunately, near-infrared TPA photodynamic therapy has never reached its full potentials due to the absence of the criteria for the design of photosensitizers with large twophoton absorption cross sections and high singlet oxygen quantum yields. Bromine substitution is considered to be efficient approach to increase the quantum yields of singlet oxygen of TPA photosensitizers [16]. To our limited knowledge, it is unclear if bromine substitution has effects on the TPA properties of triplet photosenstitizers so far (if yes, how big and why?).…”

mentioning

confidence: 99%

“…Tables 1 and 2 also showed that the absorption maxima, one-and two-photon emission maxima of the branched photosensitizers were red-shifted with respect to the linear ones respectively, which could be ascribed to the larger dipole moment changes and the lower HOMO-LUMO gaps of the branched photosensitizers in G2 as well (Table S1). According to Kasha's rule, the production of singlet oxygen is irrespective of the method by which initial excitation is realized, and thus the quantum yield of singlet oxygen generated upon two-photon excitation is considered to be the same as that produced upon one-photon excitation [16,17,20]. One-photon singlet oxygen quantum yields of the photosensitizers were determined by the photobleaching method of 9,10-diphenylanthracene (DPA) in this experiment (see the Supporting Information), and the data were also listed in Table 2.…”

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confidence: 99%

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Significant effects of branches and bromine substitution of near-infrared two-photon photosensitizers on the generation of singlet oxygen

et al. 2012

Chin. Sci. Bull.

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This letter reports the influence of branches and bromine substitution of the photosensitizers on one-and two-photon absorption generation of singlet oxygen. Near-infrared femtosecond Ti:squassier laser was utilized to determine two-photon properties of the photosensitizers tuning wavelength from 700 to 880 nm at intervals of 20 nm. One-and two-photon optical and photophysical properties of the photosensitizers show significant dependence on the branches and substituted bromine atoms. two-photon absorption, singlet oxygen, photosensitizers Citation:Li H R, Ye X J, Liu M, et al. Significant effects of branches and bromine substitution of near-infrared two-photon photosensitizers on the generation of singlet oxygen. Chin Sci Bull, 2012Bull, , 57: 38503854, doi: : 10.1007 Numerous efforts have been devoted to singlet oxygen ( 1 O 2 ) since its discovery in the 1960s [1,2], which plays significantly important role in photodynamic therapy (PDT) due to its efficient damage to tumor cells [3][4][5][6][7][8][9][10][11]. Near-infrared photon has remarkable advantage, such as low energy, excellent penetration and negligible damage to normal biological tissues. Hence, the utilization of near-IR laser to irradiate two-photon triplet photosensitizers to generate singlet oxygen receives considerable attentions [12][13][14][15][16][17][18]. While unfortunately, near-infrared TPA photodynamic therapy has never reached its full potentials due to the absence of the criteria for the design of photosensitizers with large twophoton absorption cross sections and high singlet oxygen quantum yields. Bromine substitution is considered to be efficient approach to increase the quantum yields of singlet oxygen of TPA photosensitizers [16]. To our limited knowledge, it is unclear if bromine substitution has effects on the TPA properties of triplet photosenstitizers so far (if yes, how big and why?). It is necessary to investigate the structure-activity interrelationship so that it would provide the guidance to develop efficient TPA triplet photosensitizer for near-infrared PDT. Here, we present our recent efforts to clarify the effect of the branches and bromine substitution on one-and two-photon optical and photochemical properties of TPA photosensitizers. These photosensitizers divided by two groups (G1 and G2) shown in Scheme 1 were obtained with satisfactory yields according to the routine procedures (Scheme S1), in which C2C4 and C6C8 were reported firstly herein.Typical linear absorption and fluorescence spectra of the photosensitizers in tetrahydronfuran (THF) were presented in Figure 1. As shown in Figure 1(a) and (b), the ultraviolet/ visible absorption spectra of these photosensitizers are affected by the bromine substitution, which plays more remarkable effects on the one-photon emission spectra of the photosensitizers. Figure 1(c) and (b) showed that one-photon emission of the photosensitizers of G1 and G2 were reduced gradually with the amount of substituted bromine atoms in THF respectively. It is accepted well that heavy ...

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Two-Photon Photosensitized Production of Singlet Oxygen

Cited by 259 publications

References 21 publications

Effects of (Multi)branching of Dipolar Chromophores on Photophysical Properties and Two-Photon Absorption

Effects of (Multi)branching of Dipolar Chromophores on Photophysical Properties and Two-Photon Absorption

Fluorescent Dyes Used in Polymer Carriers as Imaging Agents in Anticancer Therapy

Significant effects of branches and bromine substitution of near-infrared two-photon photosensitizers on the generation of singlet oxygen

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