Jun Ozawa scite author profile

A silver-catalyzed chlorination of benzylic, tertiary, and secondary C(sp)-H bonds was developed. The reaction proceeded with as low as 0.2 mol % catalyst loading at room temperature under air atmosphere with synthetically useful functional group compatibility. The regioselectivity and reactivity tendencies suggest that the chlorination proceeded through a radical pathway, but an intermediate alkylsilver species cannot be ruled out.

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Chemo- and regioselective oxygenation of C(sp³)–H bonds in aliphatic alcohols using a covalently bound directing activator and atmospheric oxygen

Ozawa

Tashiro

et al. 2016

Chem. Sci.

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Directing activator-assisted regio- and oxidation state-selective aerobic oxidation of secondary C(sp³)–H bonds in aliphatic alcohols

Ozawa

Oisaki

et al. 2016

Org. Biomol. Chem.

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The regioselective conversion of an unactivated C(sp(3))-H bond of a methylene carbon (CH2) into a C-O single bond is an attractive reaction in organic synthesis. Herein, we present a strategy for a regio- and oxidation state-selective aerobic C-H oxidation based on an N-hydroxyamide-derived directing activator (DA), which is attached to a hydroxy group in alcohol substrates. The DA reacts with NOx species generated in situ from NaNO2, a Brønsted acid, and aerobic oxygen, and effectively generates an amidoxyl radical from the N-hydroxy moiety of the DA. Then, the amidoxyl radical promotes site-selective intramolecular C-H abstraction from methylenes with γ- (or δ-) selectivity. The thus-generated methylene radicals are trapped by molecular oxygen and NO. This process results in the predominant formation of nitrate esters as products, which suppresses undesired overoxidation. The products can be easily converted into alcohols after hydrogenolysis.

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Visualized and Quantitative Conformational Analysis of Peptidomimetics

Takashima

Yoshimori²,

Honda

et al. 2021

ACS Omega

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Protein−protein interactions (PPIs) are fundamentally important and challenging drug targets. Peptidomimetic molecules of various types have been developed to modulate PPIs. A particularly promising drug discovery strategy, structural peptidomimetics, was designed based on special mimicking of sidechain C α −C β bonds. It is simple and versatile. Nevertheless, no quantitative method has been established to evaluate its similarity to a target peptide motif. We developed two methods that enable visual, comprehensive, and quantitative analysis of peptidomimetics: peptide conformation distribution (PCD) plot and peptidomimetic analysis (PMA) map. These methods specifically examine multiple side-chain C α −C β bonds of a peptide fragment motif and their corresponding bonds (pseudo-C α −C β bonds) in a mimetic molecule instead of φ and ψ angles of a single amino acid in the traditional Ramachandran plot. The PCD plot is an alignment-free method, whereas the PMA map is an alignment-based method providing distinctive and complementary analysis. Results obtained from analysis using these two methods indicate our multifacial α-helix mimetic scaffold 12 as an excellent peptidomimetic that can precisely mimic the spatial positioning of side-chain functional groups of α-helix. These methods are useful for visualized and quantified evaluation of peptidomimetics and for the rational design of new mimetic scaffolds.

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ChemInform Abstract: Directing Activator‐Assisted Regio‐ and Oxidation State‐Selective Aerobic Oxidation of Secondary C(sp³)—H Bonds in Aliphatic Alcohols.

Ozawa

Oisaki

et al. 2016

ChemInform

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Jun Ozawa

Silver-Catalyzed C(sp³)–H Chlorination

Chemo- and regioselective oxygenation of C(sp³)–H bonds in aliphatic alcohols using a covalently bound directing activator and atmospheric oxygen

Directing activator-assisted regio- and oxidation state-selective aerobic oxidation of secondary C(sp³)–H bonds in aliphatic alcohols

Visualized and Quantitative Conformational Analysis of Peptidomimetics

ChemInform Abstract: Directing Activator‐Assisted Regio‐ and Oxidation State‐Selective Aerobic Oxidation of Secondary C(sp³)—H Bonds in Aliphatic Alcohols.

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About

Jun Ozawa

Silver-Catalyzed C(sp3)–H Chlorination

Chemo- and regioselective oxygenation of C(sp3)–H bonds in aliphatic alcohols using a covalently bound directing activator and atmospheric oxygen

Directing activator-assisted regio- and oxidation state-selective aerobic oxidation of secondary C(sp3)–H bonds in aliphatic alcohols

Visualized and Quantitative Conformational Analysis of Peptidomimetics

ChemInform Abstract: Directing Activator‐Assisted Regio‐ and Oxidation State‐Selective Aerobic Oxidation of Secondary C(sp3)—H Bonds in Aliphatic Alcohols.

Contact Info

Product

Resources

About

Silver-Catalyzed C(sp³)–H Chlorination

Chemo- and regioselective oxygenation of C(sp³)–H bonds in aliphatic alcohols using a covalently bound directing activator and atmospheric oxygen

Directing activator-assisted regio- and oxidation state-selective aerobic oxidation of secondary C(sp³)–H bonds in aliphatic alcohols

ChemInform Abstract: Directing Activator‐Assisted Regio‐ and Oxidation State‐Selective Aerobic Oxidation of Secondary C(sp³)—H Bonds in Aliphatic Alcohols.