Phototriggered Release of a Leaving Group in Ketoprofen Derivatives via a Benzylic Carbanion Pathway, But not via a Biradical Pathway

Li, Ming‐De; Su, Tao; Ma, Jiani; Liu, Mingyue; Liu, Han; Li, Xuechen; Phillips, David Lee

doi:10.1002/chem.201300285

Cited by 16 publications

(28 citation statements)

References 31 publications

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“…Furthermore, the photodissociation will produce highly reactive radical species able to react with biological macromolecules. In addition, and coherently with our scenario, photodissociation of triplet state protonated ketoprofen 51 , 52 , following proton transfer from the carboxylic to the carbonyl group has been reported 80 . However, differently from benzophenone, and due to the influence of the negative charge of its salt form, ketoprofen only exhibits metastable interactions with DNA.…”

Section: Discussionsupporting

confidence: 87%

Ibuprofen and ketoprofen potentiate UVA-induced cell death by a photosensitization process

Bignon

Marazzi

Besancenot

et al. 2017

Sci Rep

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Nonsteroidal 2-arylproprionic acids are widely used, over-the-counter, anti-inflammatory drugs. Photosensitivity is a commonly overlooked adverse effect of these drugs. Based on the combined use of cell viability assays and molecular modeling, we prove and rationalize the photochemical pathways triggering photosensitization for two drugs, ibuprofen and ketoprofen. As its parent compound benzophenone, ketoprofen produces singlet oxygen, upon triplet manifold population. However, ibuprofen and ketoprofen photodissociate and hence may generate two highly reactive radicals. The formation of metastable aggregates between the two drugs and B-DNA is also directly probed by molecular dynamics. Our approach characterizes the coupled influence of the drug’s intrinsic photochemistry and the interaction pattern with DNA. The photosensitization activity of nonsteroidal 2-arylproprionic acids, being added to gels and creams for topical use, should be crucially analyzed and rationalized to enact the proper preventive measures.

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Section: Discussionsupporting

confidence: 87%

Ibuprofen and ketoprofen potentiate UVA-induced cell death by a photosensitization process

Bignon

Marazzi

Besancenot

et al. 2017

Sci Rep

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“…An absorption band at 340 nm gradually decays to 328 nm while another absorption band at 575 nm grows in and shifts to 530 nm. This process is associated with intersystem crossing (ISC) from S 1 to T 1 according to its similarity to results from previous fs-TA studies of ketoprofen derivatives 21 . Then the decarboxylation reaction takes place in the triplet state as is shown in Fig.…”

Section: Resultssupporting

confidence: 61%

“…3(b) which demonstrates that the triplet with its maximum absorption bands at 530 nm and 328 nm decay while a longer wavelength broad absorption band at 610 nm grows in at the cost of triplet state from 92 ps to more than 2500 ps. The isosbestic point for this reaction clearly indicates that the KP-ibuprofen triplet anion is the precursor of the 610 nm species which is readily assigned to a KP carbanion species 21 . The corresponding kinetics of the transient absorption at 530 nm and 610 nm are shown in Fig.…”

Section: Resultsmentioning

confidence: 89%

“…For example, this photodeprotection platform denoted as “ketoprofenate derivatives” (KP-X) have many advantages such as cleanness and efficiency for release of the leaving group, good aqueous solubility and inert and non-absorbing photoproducts. Recently, KP-OAc, one of this new class of KP-X compounds has been used as a model to investigate the highly efficient phototrigger reaction in phosphate buffered aqueous solutions, (PBS) mediated by a carbanion intermediate but not taking place in an acid-assisted decarboxylation reaction 21 22 . However, the mechanism of ketoprofenate release for different substituent groups has not been so well reported and much work is still left to be done to explore how the nature of the leaving groups can influence the photodeprotection reactions of ketoprofenate derivatives.…”

mentioning

confidence: 99%

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Substituent Effects on the Photodeprotection Reactions of Selected Ketoprofen Derivatives in Phosphate Buffered Aqueous Solutions

Liu

Huang

et al. 2016

Sci Rep

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Photodeprotection is an important reaction that has been attracting broad interest for use in a variety of applications. Recent advances in ultrafast and vibrational time-resolved spectroscopies can facilitate obtaining data to help unravel the reaction mechanisms involving in the photochemical reactions of interest. The kinetics and reaction mechanisms for the photodeprotection reactions of ketoprofen derivatives containing three different substituents (ibuprofen, Br and I) were investigated by femtosecond transient absorption (fs-TA) and nanosecond time-resolved resonance Raman (ns-TR3) spectroscopy methods in phosphate buffered solutions (PBS). Fs-TA allows us to detect the decay kinetics of the triplet species as the key precursor for formation of a carbanion species for three different substituents attached to ketoprofen. To characterize the structural and electronic properties of the corresponding carbanion and triplet intermediates, TR3 spectroscopic experiments were conducted. The transient spectroscopy work reveals that the different substituents affect the photodecarboxylation reaction to produce carbon dioxide which in turn influences the generation of the carbanion species which determines the rate of the photorelease of the functional groups attached on the ketoprofen parent molecule. The fingerprint TR3 spectroscopy results suggest that ketoprofen derivatives may be deactivated to produce a triplet carbanion when increasing the atom mass of the halogen atoms.

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“…[9][10][11][12] Photocatalytic decarboxylation reactions have recently experienced a revival in organic synthesis, [13][14][15][16][17][18] and significant progress has been made to elucidate the photodecarboxylation reaction mechanism that leads to anionic species. [19][20][21][22][23][24][25][26][27][28] Photodecarboxylation can be initiated by the phthalimide chromophore in the triplet excited state, which acts as the electron acceptor in the photoinduced electron transfer (PET) reaction. [29,30] The PET-promoted decarboxylation by phthalimides has been used in macrocyclizations, [31] the cyclization of peptides, [32,33] photodecaging strategies, [34] and the enantioselective synthesis of benzodiazepines.…”

Section: Introductionmentioning

confidence: 99%

Photodecarboxylation of Adamantane Amino Acids Activated by Phthalimide

et al. 2016

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Adamantane α‐, β‐, and δ‐amino acids activated by phthalimide (i.e., 3–6) were synthesized, and their photochemical reactivities were investigated. Amino acid derivatives 3–6 underwent a photoinduced electron transfer (PET) and decarboxylation reaction sequence, most probably through a triplet excited state. The decarboxylations of the β‐amino acid derivatives were succeeded by cyclization reactions that afforded complex polycyclic molecules with potential biological interest. The adamantyl radical that is produced by the photoinduced decarboxylation could be trapped by alkenes or oxygen to deliver adducts or alcohols, respectively. The photodecarboxylation process was shown to be more efficient under acetone sensitization conditions (with quantum yields, Φ = 0.02–0.5) than upon direct excitation, and the reactivity was dependent on the chain length (intramolecular distance) between the electron donor (carboxylate) and acceptor (phthalimide in the triplet excited state) of the derivative. The formation of different radicals, that is, the 1‐ or 2‐adamantyl intermediate, probably does not affect the overall rate of the decarboxylation This current report provides a better understanding of photodecarboxylation and the rational design of molecular systems to undergo photoinduced decarboxylation and cyclization reactions.

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Phototriggered Release of a Leaving Group in Ketoprofen Derivatives via a Benzylic Carbanion Pathway, But not via a Biradical Pathway

Cited by 16 publications

References 31 publications

Ibuprofen and ketoprofen potentiate UVA-induced cell death by a photosensitization process

Ibuprofen and ketoprofen potentiate UVA-induced cell death by a photosensitization process

Substituent Effects on the Photodeprotection Reactions of Selected Ketoprofen Derivatives in Phosphate Buffered Aqueous Solutions

Photodecarboxylation of Adamantane Amino Acids Activated by Phthalimide

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