Synthesis of Azaylide‐Based Amphiphiles by the Staudinger Reaction

Yamashina, Masahiro; Suzuki, Hayate; Kishida, Natsuki; Yoshizawa, Michito; Toyota, Shinji

doi:10.1002/anie.202105094

Cited by 12 publications

(15 citation statements)

References 43 publications

(19 reference statements)

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“…In recent years, the non-hydrolytic Staudinger reaction (NSR) has attracted much attention as one of the efficient click-type reactions in bioorthogonal chemistry. − The strategy to stabilize the iminophosphorane (IPP) intermediate accompanied with a resonance contribution of aza-ylide of Staudinger reaction is mainly based on the inductive effect of the electronegative substituents adjacent to the IPP bond, which prevents the nucleophilic attack of H 2 O, yielding undesired hydrolyzed products. In addition, as the Staudinger reaction involves an initial azide group, another click reaction involving alkyne/azide cycloaddition can be combined with the NSR for creating versatile functional molecules. , Toyota and co-workers used the NSR strategy to prepare amphiphilic aza-ylide derivatives and confirmed the long-term stability of the aza-ylide structure in aqueous solution . The amphiphiles could form spherical aggregates with a size of approximately 2 nm through a self-assembly process.…”

Section: Introductionmentioning

confidence: 99%

“…8,9 Toyota and coworkers used the NSR strategy to prepare amphiphilic azaylide derivatives and confirmed the long-term stability of the aza-ylide structure in aqueous solution. 10 The amphiphiles could form spherical aggregates with a size of approximately 2 nm through a self-assembly process. Our group has used the NSR concept to synthesize a series of coumarin−triphenyliminophosphorane (TPIPP) derivatives.…”

Section: Introductionmentioning

confidence: 99%

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Polymer-Bound Coumarin–Triphenyliminophosphorane Derivatives as Turn-On Fluorescence Sensors for Water Content Detection via Non-Hydrolytic Staudinger Reaction

Lin

Chen

et al. 2022

ACS Appl. Polym. Mater.

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Fluorometric optical sensors have recently been developed for analyzing environmental humidity and solvents' water content. Our group has demonstrated a series of coumarin−triphenyliminophosphorane (TPIPP) derivatives that exhibit a remarkable fluorescence efficiency under photoexcitation. We speculated that these derivatives could be developed into turn-on fluorescent probes suitable for the analysis of water content and humidity. First, the non-hydrolytic Staudinger reaction (NSR) was employed to modify the side chain of a styrene−4-diphenylphosphino styrene (DPPS) copolymer with coumarin−TPIPP fluorophores. When the DPPS content of the copolymer was higher, the fluorophores' fluorescence was weaker because of their dense packing, causing self-quenching. When the fluorophoremodified copolymer was placed in tetrahydrofuran containing water and a small amount of AcOH, hydrolysis occurred, and highly fluorescent 7-amino-3-cyanocoumarin (coumarin 1) was released in the solvent following the general Staudinger reduction route. The release of some fluorophores from the copolymer also resulted in less self-quenching, thus enhancing the fluorescence intensity. To take full advantage of this emission, we prepared polymer beads with crosslinked poly (styrene) and poly(DPPS) and coumarin fluorophores that were covalently linked to the beads through an efficient NSR. Compared with the nonbead form, the polymer beads required a much lower acid concentration for hydrolysis to occur and solvents' fluorescence turned on more quickly. The water content in three common solvents, tetrahydrofuran, acetonitrile, and methanol, was analyzed by immersing the modified beads for 5 min (AcOH concentration = 0.5%); the respective quantitation limits were 0.067, 0.013, and 0.057%, respectively. The proposed polymer material is a promising platform for moisture detection in the chemical refinery industry.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Polymer-Bound Coumarin–Triphenyliminophosphorane Derivatives as Turn-On Fluorescence Sensors for Water Content Detection via Non-Hydrolytic Staudinger Reaction

Lin

Chen

et al. 2022

ACS Appl. Polym. Mater.

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“…The Staudinger reduction is a well-established method for the synthetic reduction of azides to amines [1,2] and has been widely used in biological and host-guest applications, [3][4][5] in part due to the mild conditions employed by such reactions, as well as their tolerance for aqueous environments. The field of phosphine-based (aza-Wittig) chemistries and their biological applications has been the subject of a recent review.…”

Section: Introductionmentioning

confidence: 99%

Kinetic and mechanistic studies of the Staudinger reduction: On the chemistry of aryl phosphazides

Corrigan

Poole

2022

J of Physical Organic Chem

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The Staudinger reduction of heteroaryl azides containing an N-oxide moiety with triphenylphosphine in mixed aqueous/THF solutions yields a mixture of amine and iminophosphorane products. A product analysis study using a combination of 1 H and 31 P NMR spectroscopic techniques indicates that in these systems, even under mild conditions, the amine product is generated, not from the hydrolysis of the iminophosphorane as expected from the standard reaction mechanism, but via hydrolysis of the phosphazide intermediate. The amount of amine generated is dependent on the structure of the starting azides, the composition of solvent, and the reaction conditions. The possible mechanisms of amine formation under acidic, neutral, and basic conditions are discussed.

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“…[19,20] Surfactants or amphiphiles consist of two different moieties, one with hydrophilic/polar and the second with hydrophobic/ non-polar character, connected via covalent and dynamic covalent bonding, as well as noncovalent interactions. [21][22][23][24][25] The latter strategy opens the possibility to combine polar and nonpolar components in a modular self-assembly approach. Recently, our group has reported a multicomponent coordination cage (CGA-1; section 1.2, Supporting Information) of anisotropic shape, comprising a polar head unit (four methoxy groups close to two cationic Pd(II) centers) and non-polar dodecyl appendices, capable of stabilizing non-aqueous emulsions.…”

Section: Introductionmentioning

confidence: 99%

“…Surfactants or amphiphiles consist of two different moieties, one with hydrophilic/polar and the second with hydrophobic/non‐polar character, connected via covalent and dynamic covalent bonding, as well as noncovalent interactions [21–25] . The latter strategy opens the possibility to combine polar and non‐polar components in a modular self‐assembly approach.…”

Section: Introductionmentioning

confidence: 99%

Coordination Cage‐Based Emulsifiers: Templated Formation of Metal Oxide Microcapsules Monitored by In Situ LC‐TEM

Saha

Chen

Ganta

et al. 2021

Chemistry A European J

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Metallo-supramolecular self-assembly has yielded a plethora of discrete nanosystems, many of which show competence in capturing guests and catalyzing chemical reactions. However, the potential of low-molecular bottom-up self-assemblies in the development of structured inorganic materials has rarely been methodically explored so far. Herein, we present a new type of metallo-supramolecular surfactant with the ability to stabilize non-aqueous emulsions for a significant period. The molecular design of the surfactant is based on a heteroleptic coordination cage (CGA-3; CGA = Cage-based Gemini Amphiphile), assembled from two pairs of organic building blocks, grouped around two Pd(II) cations. Shape-complementarity between the differently functional-ized components generates discrete amphiphiles with a tailor-made polarity profile, able to stabilize non-aqueous emulsions, such as hexadecane-in-DMSO. These emulsions were used as a medium for the synthesis of spherical metal oxide microcapsules (titanium oxide, zirconium oxide, and niobium oxide) from soluble, water-sensitive alkoxide precursors by allowing a controlled dosage of water to the liquidliquid phase boundary. Synthesized materials were analyzed by a combination of electron microscopic techniques. In situ liquid cell transmission electron microscopy (LC-TEM) was utilized for the first time to visualize the dynamics of the emulsion-templated formation of hollow inorganic titanium oxide and zirconium oxide microspheres.

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Synthesis of Azaylide‐Based Amphiphiles by the Staudinger Reaction

Cited by 12 publications

References 43 publications

Polymer-Bound Coumarin–Triphenyliminophosphorane Derivatives as Turn-On Fluorescence Sensors for Water Content Detection via Non-Hydrolytic Staudinger Reaction

Polymer-Bound Coumarin–Triphenyliminophosphorane Derivatives as Turn-On Fluorescence Sensors for Water Content Detection via Non-Hydrolytic Staudinger Reaction

Kinetic and mechanistic studies of the Staudinger reduction: On the chemistry of aryl phosphazides

Coordination Cage‐Based Emulsifiers: Templated Formation of Metal Oxide Microcapsules Monitored by In Situ LC‐TEM

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