Shuanglin Qu scite author profile

In chemodynamic therapy (CDT), novel chemodynamic reactions are urgently needed to promote the generating efficiency of reactive oxygen species (ROS), and meanwhile the real-time monitoring of ROS is really critical to minimize the toxic side effect of CDT. Herein, we develop a pH-responsive chemiluminescent and chemodynamic system (ultrathin Mn-oxides [MnOx] nanosheet -semiconducting polymer nanoparticles [SPNs]). We, for the first time, discover the capability of ultrathin MnOx nanosheets to generate 1 O 2 under the trigger of acidity. Notably, the 1 O 2 produced by MnOx can substitute light and specifically excite thiophene-based SPNs to emit photons for near-infrared chemiluminescent imaging, which greatly amplifies the generation of 1 O 2 . Because of the intrinsic acidity within tumor, MnOx-SPNs realize the activatable chemodynamic therapy for solid tumor. Furthermore, the ratiometric chemiluminescent/fluorescent imaging is able to calibrate the output of 1 O 2 and achieve more accurate real-time and in situ monitoring of 1 O 2 production during therapy.

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Catalytic Mechanisms of Direct Pyrrole Synthesis via Dehydrogenative Coupling Mediated by PNP-Ir or PNN-Ru Pincer Complexes: Crucial Role of Proton-Transfer Shuttles in the PNP-Ir System

Dang

et al. 2014

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Kempe et al. and Milstein et al. have recently advanced the dehydrogenative coupling methodology to synthesize pyrroles from secondary alcohols (e.g., 3) and β-amino alcohols (e.g., 4), using PNP-Ir (1) and PNN-Ru (2) pincer complexes, respectively. We herein present a DFT study to characterize the catalytic mechanism of these reactions. After precatalyst activation to give active 1A/2A, the transformation proceeds via four stages: 1A/2A-catalyzed alcohol (3) dehydrogenation to give ketone (11), base-facilitated C-N coupling of 11 and 4 to form an imine-alcohol intermediate (18), base-promoted cyclization of 18, and catalyst regeneration via H2 release from 1R/2R. For alcohol dehydrogenations, the bifunctional double hydrogen-transfer pathway is more favorable than that via β-hydride elimination. Generally, proton-transfer (H-transfer) shuttles facilitate various H-transfer processes in both systems. Notwithstanding, H-transfer shuttles play a much more crucial role in the PNP-Ir system than in the PNN-Ru system. Without H-transfer shuttles, the key barriers up to 45.9 kcal/mol in PNP-Ir system are too high to be accessible, while the corresponding barriers (<32.0 kcal/mol) in PNN-Ru system are not unreachable. Another significant difference between the two systems is that the addition of alcohol to 1A giving an alkoxo complex is endergonic by 8.1 kcal/mol, whereas the addition to 2A is exergonic by 8.9 kcal/mol. The thermodynamic difference could be the main reason for PNP-Ir system requiring lower catalyst loading than the PNN-Ru system. We discuss how the differences are resulted in terms of electronic and geometric structures of the catalysts and how to use the features in catalyst development.

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A Computational Mechanistic Study of an Unprecedented Heck-Type Relay Reaction: Insight into the Origins of Regio- and Enantioselectivities

et al. 2014

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Density functional theory (DFT) calculations (B3LYP and M06) have been utilized to study a newly reported Heck-type reaction that uses an allylic or alkenyl alcohol as substrate and palladium as catalyst in the form of a chelate with a chiral pyridine oxazoline (PyrOx) ligand. The reaction not only controls the regio- and enantioselectivities of arylation of the C═C bond, but also forms the carbonyl functionality up to four bonds away from the aryl substituent via tandem C═C bond migration and enol-to-keto conversion. Computations performed on representative reaction systems allow us to propose a detailed mechanism with several key steps. Initial oxidation of palladium(0) by aryldiazonium generates active arylpalladium(II) species that bind the C═C bond of an allylic or alkenyl alcohol. The activated C═C bond inserts into the palladium-aryl moiety to attain aryl substitution and a chiral carbon center, and the resulting complex undergoes β-hydride elimination to give a new C═C bond that can repeat the insertion/elimination process to move down the carbon chain to form an enol that tautomerizes to a highly stable carbonyl final product. The calculations reveal that the C═C bond migratory insertion step determines both the regioselectivity and the enantioselectivity of arylation, with the former arising mainly from the electronic effect of the hydroxyl group on the charge distribution over the C═C bond and the latter originating from a combination of steric repulsion, trans influence, and C-H/π dispersion interactions.

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Mechanism of the Methyltrioxorhenium‐Catalyzed Deoxydehydration of Polyols: A New Pathway Revealed

Dang

Wen

et al. 2013

Chemistry A European J

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Palladium-Catalyzed Carbene Migratory Insertion Using Conjugated Ene–Yne–Ketones as Carbene Precursors

et al. 2013

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Palladium-catalyzed cross-coupling reactions between benzyl, aryl, or allyl bromides and conjugated ene-yne-ketones lead to the formation of 2-alkenyl-substituted furans. This novel coupling reaction involves oxidative addition, alkyne activation-cyclization, palladium carbene migratory insertion, β-hydride elimination, and catalyst regeneration. Palladium (2-furyl)carbene is proposed as the key intermediate, which is supported by DFT calculations. The palladium carbene character of the key intermediate is validated by three aspects, including bond lengths, Wiberg bond order indices, and molecular orbitals, by comparison to those reported for stable palladium carbene species. Computational studies also revealed that the rate-limiting step is ene-yne-ketone cyclization, which leads to the formation of the palladium (2-furyl)carbene, while the subsequent carbene migratory insertion is a facile process with a low energy barrier (<5 kcal/mol).

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Shuanglin Qu

Light-free Generation of Singlet Oxygen through Manganese-Thiophene Nanosystems for pH-Responsive Chemiluminescence Imaging and Tumor Therapy

Catalytic Mechanisms of Direct Pyrrole Synthesis via Dehydrogenative Coupling Mediated by PNP-Ir or PNN-Ru Pincer Complexes: Crucial Role of Proton-Transfer Shuttles in the PNP-Ir System

A Computational Mechanistic Study of an Unprecedented Heck-Type Relay Reaction: Insight into the Origins of Regio- and Enantioselectivities

Mechanism of the Methyltrioxorhenium‐Catalyzed Deoxydehydration of Polyols: A New Pathway Revealed

Palladium-Catalyzed Carbene Migratory Insertion Using Conjugated Ene–Yne–Ketones as Carbene Precursors

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