Spin selectivity in the oxygenation of singlet phenylhalocarbenes with oxygen

Singlet phenylhalocarbenes are shown to react with triplet oxygen and the apparent spin-forbidden oxygenation rates are strongly dependent on substituents, i.e. in the decreasing order of Br>Cl?F for halogen and of p-NO₂>H?p-MeO for p-substituents. These results suggest the oxygenation of triplet halocarbene equilibrated with ground-state singlet, resulting in the first estimation of energy difference between the singlet and triplet states.     

Temperature-driven oxygenation rate control by polymeric photosensitizer

A polymeric photosensitizer, poly(NIPAM-co-BP), consisting of N-isopropylacrylamide (NIPAM) and benzophenone (BP) units, demonstrates a temperature-controlled oxygenation activity in water. The system promotes a heat-induced oxygenation enhancement at <17 degrees C and suppression at >22 degrees C. This unprecedented photo-oxygenation activity is triggered by a heat-induced phase transition of the polymer from coil to micelle, and then to globule state, cleverly controlling the stability and diffusion of singlet oxygen and the location of substrate.     

Controlled generation of singlet oxygen by a water-soluble meso-pyrenylporphyrin photosensitizer through interaction with DNA

An electron donor-connecting water-soluble porphyrin, meso-(1-pyrenyl)-tris(N-methyl-p-pyridinio)porphyrin, did not demonstrate singlet oxygen generating activity under photo-irradiation. The interaction with DNA successfully recovered the photosensitized singlet oxygen generation by this porphyrin.     

A singlet oxygen self-reporting photosensitizer for cancer phototherapy

Photodynamic cancer therapy has attracted great attention with the increasing threat of tumors, and improving its therapeutic efficacy is highly desirable. However, due to the highly efficient intersystem crossing potency to generate singlet oxygen (¹O₂), high-efficiency photosensitizers often suffer from weak fluorescence and excess injury to normal tissue. To overcome these obstacles, here we show a reliable self-reporting strategy for real-time monitoring of therapeutic progression. As a proof of concept, a molecular dyad is designed by connecting benzo[a]phenoselenazinium (NBSe) to rhodamine (Rh), namely Rh-NBSe, where the fluorescence of the Rh unit is initially suppressed by the fluorescence resonance energy transfer mechanism, but enabled to recover as feedback signal once the reaction with photosensitized ¹O₂ takes place. The observed fluorescence increases by irradiation in vitro and in vivo successfully reflect the real-time ¹O₂ generation speed in photodynamic therapy. In addition, the favorable therapeutic advantages of Rh-NBSe are also verified, for example, the high Φ_Δ (0.8) and the low IC₅₀ (0.2 μM, 6 J cm⁻²). Based on the therapeutic ability and real-time ¹O₂ self-reporting ability, Rh-NBSe demonstrates significant potential for self-regulating phototherapy.

Photodynamic cancer therapy has attracted great attention with the increasing threat of tumors, and improving its therapeutic efficacy is highly desirable.     

Temperature-controlled photooxygenation with polymer nanocapsules encapsulating an organic photosensitizer

A cross-linked poly- N-isopropylacrylamide (polyNIPAM) nanocapsule, TH@PC, containing thionine (TH), an organic photosensitizer, has been synthesized. This capsulated polymeric photosensitizer promotes a singlet oxygen oxygenation ( (1)O 2) accurately controlled by temperature: it shows high oxygenation activity at low temperature, but shows activity decrease with a rise in temperature, resulting in almost zero activity at >40 degrees C. The clear on-off activity control is driven by a heat-induced structure change of the capsule from the swollen single capsule to contracted state, and then to aggregate, behaving as an intelligent (1)O 2 filter. At low temperature, the capsule exists as the swollen single capsule, which allows (1)O 2 diffusion to bulk water, resulting in high oxygenation activity. A rise in temperature leads to contraction of the capsule, reducing the mesh size of the capsule wall. This suppresses (1)O 2 diffusion to bulk water and shows decreased activity. Intercapsule aggregation at >30 degrees C further suppresses (1)O 2 diffusion and shows almost no activity. The capsule promotes reversible activity control regardless of the heating/cooling process and can be reused with a simple recovery process.     

Fluorine end-capped optical fibers for photosensitizer release and singlet oxygen production

The usefulness of a fiber optic technique for generating singlet oxygen and releasing the pheophorbide photosensitizer has been increased by the fluorination of the porous Vycor glass tip. Singlet oxygen emerges through the fiber tip with 669-nm light and oxygen, releasing the sensitizer molecules upon a [2 + 2] addition of singlet oxygen with the ethene spacer and scission of a dioxetane intermediate. Switching from a nonfluorinated to a fluorinated glass tip led to a clear reduction of the adsorbtive affinity of the departing sensitizer with improved release into homogeneous toluene solution and bovine tissue, but no difference was found in water since the sensitizer was insoluble. High surface coverage of the nonafluorohexylsilane enhanced the cleavage efficiency by 15% at the ethene site. The fluorosilane groups also caused crowding and seemed to reduce access of (1)O(2) to the ethene site, which attenuated the total quenching rate constant k(T), although there was less wasted (1)O(2) (from surface physical quenching) at the fluorosilane-coated than the native SiOH silica. The observations support a quenching mechanism that the replacement of the SiOH groups for the fluorosilane C-H and C-F groups enhanced the (1)O(2) lifetime at the fiber tip interface due to less efficient electronic-to-vibronic energy transfer.     

Merbromin (mercurochrome)--a photosensitizer for singlet oxygen reactions.

Merbromin, produced in many countries and used world wide as an antiseptic under the trademark "mercurochrome", is shown to be an efficient sensitizer for type II (singlet oxygen) photo-oxygenations by using 2-methyl-2-butene, (+)-limonene, (+)-alpha-pinene, alpha,alpha'-dimethylstilbenes and (--)-L-methionine as oxygen acceptors. Type I photo-oxygenations are negligible. An estimate of the quantum yield of singlet oxygen formation by merbromin in methanol gives a value of about 0.1.     

A hand-held fiber-optic implement for the site-specific delivery of photosensitizer and singlet oxygen

We have constructed a fiber optic device that internally flows triplet oxygen and externally produces singlet oxygen, causing a reaction at the (Z)-1,2-dialkoxyethene spacer group, freeing a pheophorbide sensitizer upon the fragmentation of a reactive dioxetane intermediate. The device can be operated and sensitizer photorelease observed using absorption and fluorescence spectroscopy. We demonstrate the preference of sensitizer photorelease when the probe tip is in contact with octanol or lipophilic media. A first-order photocleavage rate constant of 1.13 h(-1) was measured in octanol where dye desorption was not accompanied by readsorption. When the probe tip contacts aqueous solution, the photorelease was inefficient because most of the dye adsorbed on the probe tip, even after the covalent ethene spacer bonds have been broken. The observed stability of the free sensitizer in lipophilic media is reasonable even though it is a pyropheophorbide-a derivative that carries a p-formylbenzylic alcohol substituent at the carboxylic acid group. In octanol or lipid systems, we found that the dye was not susceptible to hydrolysis to pyropheophorbide-a, otherwise a pH effect was observed in a binary methanol-water system (9:1) at pH below 2 or above 8.     

Imidazole functionalized magnesium phthalocyanine photosensitizer: modified photophysics, singlet oxygen generation and photooxidation mechanism

Magnesium phthalocyanine (MgPc) was covalently attached by four imidazole units to form a novel photosensitizer (PS). The photophysical processes within the dyad PS were explored by steady state and time-resolved fluorescence as well as laser flash photolysis. Although the imidazole units caused a 50% decrease in fluorescence quantum yield and a remarkable shortening of fluorescence lifetime of the MgPc moiety, the triplet yield (Φ(T)) is higher and the triplet lifetime becomes longer. The transient absorption bands for MgPc(?-) were observed, indicating the occurrence of intramolecular photoinduced electron transfer (PET) from imidazole subunits to the lowest excited singlet state (S(1)) of the MgPc moiety. The kinetic and thermodynamic analysis also supports the involvement of PET in S(1) deactivation. The quantum efficiency of photosensitized oxidation of diphenylisobenzofuran (DPBF) by the PS is 0.52. This value is much higher than Φ(T) (0.26), since DPBF is photo-oxidized not only by singlet oxygen (type II reaction, 54%) but also by superoxide anion radical (type I reaction, 46%). The result suggests that the mechanism of photosensitized oxidation could be changed upon the conjugation of a PS to biological molecules, so that the importance of type I reaction is enhanced.     

Unexpected products via singlet oxygen oxygenation of functionalized 5,6-dihydro-1,4-oxathiins

[formula: see text] Single oxygen oxygenation of 5,6-dihydro-1,4-oxathiins substituted at C-3 with an electron-withdrawing group leads stereoselectively to ketosulfoxides 5 and 6, instead of the expected dicarbonyl compounds 3. A mechanism involving an unprecedented intramolecular rearrangement of the corresponding dioxetanes 2 is proposed.     

Kinetics of the oxygenation of unsaturated organics with singlet oxygen generated from H2O2 by a heterogeneous molybdenum catalyst

A heterogeneous catalyst containing MoO42- exchanged on layered double hydroxides (Mo-LDHs) is used to produce 1O2 from H2O2, and with this dark 1O2, unsaturated hydrocarbons are oxidized in allylic peroxides. The oxidation kinetics are studied in detail and are compared with the kinetics of oxidation by 1O2, formed from H2O2 by a homogeneous catalyst. A model is proposed for the heterogeneously catalyzed 1O2 generation and peroxide formation. The model divides the reaction suspension in two compartments: (1) the intralamellar and intragranular zones of the LDH catalyst; (2) the bulk solution. The 2-compartment model correctly predicts the oxidant efficiency and peroxide yield for a series of olefin peroxidation reactions. 1O2 is generated at a high rate by the heterogeneous catalyst, but somewhat more 1O2 is lost by quenching with the heterogeneous catalyst than using the homogeneous catalyst. Quenching occurs mainly as a result of collision with the LDH hydroxyl surface, as is evidenced by using LDH supports containing strong 1O2 deactivators such as Ni2+. A total of 15 organic substrates were peroxidized on a preparative scale using the best Mo-LDH catalyst under optimal conditions.     

Reaction of singlet oxygen with sulfide: A similarity of singlet oxygenation and coupling reaction of cation radical and superoxide ion

Photosensitized oxygenation of 5H,7H-dibenzo[b,g][1,5]dithiocin afforded the sulfoxides. The reaction of its cation radical derived from oxidation by nitrosyl tetrafluoroborate with superoxide ion gave the same products.     

Quenching of singlet oxygen by alkenes with a hindered double bond

Both the chemical reaction of oxidation and the physical deactivation of¹O₂ caused by the dimension of the exciting energy in vibrations of the C-H bonds of the molecule of the quenching agent play an important role in quenching of singlet oxygen by substituted adamantylidenenorbornanes with a hindered double bond. The substituents which shield the double bond have a stereoelectronic effect on the reaction of 1,2-cycloaddition of singlet oxygen. The almost total inhibition of the oxidation reaction is possible as a function of their position.Translated from Izvestiya Akademii Nauk SSSR, Seriya Khimicheskaya, No. 2, pp. 286–289, February, 1990.We would like to thank B. M. Lerman and T. A. Belogaeva for synthesis of samples (II)-(IV).     

Quenching of singlet oxygen by phenols

The rate constants for the quenching of singlet oxygen by sterically hindered phenols were determined. It was observed that the rate constant for the quenching increases with a decrease in the ionization potential of phenols.Translated fromIzvestiya Akademii Nauk. Seriya Khimicheskaya, No. 12, pp. 2132–2134, December, 1993.This work was supported by the Russian Foundation for Basic Research (Grant 93-03-5231).     

Calculation of singlet oxygen dose from photosensitizer fluorescence and photobleaching during mTHPC photodynamic therapy of MLL cells

Predicting the therapeutic outcome of photodynamic therapy (PDT) requires knowledge of the amount of cytoxic species generated. An implicit approach to assessing PDT efficacy has been proposed where changes in photosensitizer (PS) fluorescence during treatment are used to predict treatment outcome. To investigate this, in vitro experiments were performed in which Mat-LyLu cells were incubated in meta-tetra(hydroxyphenyl)chlorin (mTHPC) and then irradiated with 652 nm light. PS concentration, fluence rate and oxygenation were independently controlled and monitored during the treatment. Fluorescence of mTHPC was monitored during treatment and, at selected fluence levels, cell viability was determined using a colony-formation assay. Singlet oxygen dose was calculated using four different models and was compared with cell survival. For the dose metric based on singlet oxygen-mediated PS photobleaching, a universal relationship between cell survival and singlet oxygen dose was found for all treatment parameters. Analysis of the concentration dependence of bleaching suggests that the lifetime of singlet oxygen within the cell is 0.05-0.25 micros. Generation of about 9 x 10(8) molecules of singlet oxygen per cell reduces the surviving fraction by 1/e.     

Chemistry of singlet oxygen with arylphosphines

The chemistry of singlet oxygen with a variety of arylphosphines has been studied. Rates of singlet oxygen removal by para-substituted arylphosphines show good correlation with the Hammett σ parameter (ρ=−1.53 in CDCl₃), and with the Tolman electronic parameter. The only products for the reactions of these phosphines with singlet oxygen are the corresponding phosphine oxides. Conversely, for ortho-substituted phosphines with electron-donating substituents, there are two products, namely a phosphinate formed by intramolecular insertion and phosphine oxide. Kinetic analyses demonstrate that both products are formed from the same intermediate, and this allows determination of the rate ratios for the competing pathways. Increasing the steric bulk of the phosphine leads to an increase in the amount of insertion product. VT NMR experiments show that peroxidic intermediates can only be detected for very hindered and very electron-rich arylphosphines.     

Reactions of singlet oxygen with biomolecules

Rate constants of singlet oxygen quenching by glycyrrhetic acid, glycyrrhizic acid, isoliquiritigenin, licurazide,d-glucose, andl-arabinose were determined. An increase in the quenching rate constants by more than an order of magnitude is observed on going from aglycone to the corresponding glycoside.Translated fromIzvestiya Akademii Nauk. Seriya Khimicheskaya, No. 1, pp. 57–59, January, 1996.     

Binding of singlet oxygen with a stacked guanine dimer

Geometry optimization calculations were performed using the B3LYP/6‐31+G* method on the complexes of ¹O₂ and ³O₂ molecules with a stacked dimer of planar guanine, varying the distance (D) between the planes of the guanine molecules. In this process, geometries of the guanine molecules were held fixed, D was fixed at different values, while the bond lengths of ¹O₂ and ³O₂ as well as their orientations with respect to the guanine molecules were optimized for each value of D. The complexes in their most stable geometries were solvated in water using the integral equation formalism of the polarized continuum model of the self‐consistent reaction field theory. In gas phase, the most stable complex between ¹O₂ and the guanine dimer (2G.¹O₂) is formed when D is about 6 Å, while the most stable complex between ³O₂ and the guanine dimer (2G.³O₂) is formed when D is about 3.75 Å. In the minimum total energy geometry of 2G.¹O₂, ¹O₂ is located between the guanine molecules, above the imidazole ring of one of them. However, in the minimum total energy geometry of 2G.³O₂, ³O₂ is located outside the stack of guanine molecules, near the amino group of one of them. The solvation calculations showed that in aqueous media, ¹O₂ would bind with the stacked guanine dimer more strongly than in gas phase, while ³O₂ would not bind with the same. The mode of binding of ¹O₂ with the stacked guanine dimer is such that it seems that ¹O₂ would replace one basepair in DNA, as happens in the intercalative mode of binding of drugs and other molecules, and it can lead to the formation of 8‐oxoguanine that has a mutagenic nature. © 2004 Wiley Periodicals, Inc. Int J Quantum Chem, 2005